Computer-aided aptamers screening technologies: a review / 生物工程学报

The computer information technology that has penetrated into every aspect of our lives, can not only assist the screening of drugs, but also simulate the effect of drugs. At present, computer-aided technologies have been used to screen aptamers, which play an important role in improving the screening efficiency and screening high affinity binding aptamers. This review summarized the screening methods of aptamers through computer-aided sequence evaluation, structural analysis and molecular docking.

Identification of new human mesenchymal stem cell biomarker by aptamers / Identificação de novos biomarcadores de células tronco mesenquimais de origem humana por meio de aptâmeros

Stem cells are undifferentiated cells that can be distinguished from others by their ability to self-renew and to differentiate into new specific cell types. Mesenchymal stem cells (MSC) are adult stem cells that can be obtained from different sources, such as adipose tissue, bone marrow, dental pulp, and umbilical cord. They can either replicate, originating new identical cells, or differentiate into cells of mesodermal origin and from other germ layers. MSC have been studied as new tools for regenerative therapy. Although encouraging results have been demonstrated, MSC-based therapies still face a great barrier: the difficulty of isolating these cells from heterogeneous environments. MSC are currently characterized by immunolabelling through a set of multiple surface membrane markers, including CD29, CD73, CD90 and CD105, which are also expressed by other cell types. Hence, the present work aimed to identify new specific biomarkers for the characterization of human MSC using DNA aptamers produced by the SELEX (Systematic Evolution of Ligands by EXponential Enrichment) technique. Our results showed that MSC from different origins bound to DNA candidate aptamers, that is, DNA or RNA oligonucleotides selected from random libraries that bind specifically to biological targets. Aptamer-bound MSC could be isolated by fluorescenceactivated cell sorting (FACS) procedures, enhancing the induction of differentiation into specific phenotypes (chondrocytes, osteocytes and adipocytes) when compared to the whole MSC population. Flow cytometry analyses revealed that candidate aptamers bound to 50% of the MSC population from dental pulp and did not present significant binding rates to human fibroblasts or lymphocytes, both used as negative control. Moreover, immunofluorescence images and confocal analyses revealed staining of MSC by aptamers localized in the surfacemembrane of these cells. The results also showed internal staining of human monocytes by our investigated aptamers. A non-specific control aptamer (CNTR APT) obtained from the random pool was then utilized to compare the specificity of the aptamers bound to the analyzed non-apoptotic cells, showing no staining for MSC. However, 40% of the monocytes bound to the CNTR APT. Normalized data based on the cells bound to candidate aptamers compared to those bound to the CNTR APT, revealed a 10 to 16-fold higher binding rate for MSC against 2-fold for monocytes. Despite its low specificity, monocyte-aptamer binding occurs probably due to the expression of shared markers with MSC, since monocytes are derived from hematopoietic stem cells and are important for the immune system ability to internalize/phagocyte external molecules. Given that, we performed a pull-down assay followed by mass spectrometry analysis to detect which MSC-specific protein or other target epitope not coexpressed by monocytes or the CNTR APT would bind to the candidate aptamer. Distinguishing between MSC and monocyte epitopes is important, as both cells are involved in immunomodulatory effects after MSC transplantations. ADAM17 was found to be a target of the APT10, emerging as a possible biomarker of MSC, since its involvement in the inhibition of the TGF signaling cascade, which is responsible for the differentiation of MSC. Thus, MSC with a higher stemness profile should overexpress the protein ADAM17, which presents a catalytic site with affinity to APT10. Another target of Apt 10 is VAMP3, belonging to a transmembrane protein complex that is involved in endocytosis and exocytosis processes during immune and inflammatory responses. Overall, proteins identified as targets of APT10 may be cell surface MSC biomarkers, with importance for MSC-based cell and immune therapies

Células tronco são células indiferenciadas que podem ser distinguidas de outros tipos celulares por meio da habilidade de se auto renovarem e de se diferenciarem em novos tipos celulares. Células tronco mesenquimais (MSC) são células tronco adultas encontradas em diferentes tecidos como tecido adiposo, polpa de dente e cordão umbilical. Estas células podem se autodividir em células idênticas ou se diferenciarem em células de origem mesodermal. Estas células têm sido estudadas em novas aplicações que envolvem terapia regenerativas. Embora resultados encorajadores tenham sido demonstrados, terapias que utilizam MSC ainda encontram uma grande barreira: a dificuldade no isolamento destas células a partir de um ambiente heterogêneo. MSC são caracterizadas por populações positivas em ensaios de imunomarcação para os epítopos membranares CD29, CD73, CD90 e CD105, presentes também em outros tipos celulares. Assim, o presente trabalho tem o objetivo de identificar novos biomarcadores de MSC de origem humana, utilizando aptâmeros de DNA produzidos pela técnica SELEX (Systematic Evolution of Ligands by EXponential Enrichment) como ferramenta. Nossos resultados mostraram que MSC de diferentes origens ligam-se a aptâmeros (oligonucleotídeos de DNA ou RNA que atuam como ligantes específicos de alvos moleculares) de DNA candidatos que atuam no isolamento de MSC por meio da técnica FACS de separação celular, promovendo uma maior indução de diferenciação em células específicas (condrócitos, osteócitos e adipócitos) comparada com a população total de MSC. Análises de citometria de fluxo mostraram que os aptâmeros candidatos se ligam a 50% das MSC de polpa de dente e não apresentam taxa de ligação significante para fibroblastos e linfócitos de origem humana - utilizados como controles negativo. Além domais, imagens de imunofluorescência e confocal mostraram ligação na superfície da membrana de MSC e a marcação interna de monócitos a estes aptâmeros. Portanto, um aptâmero controle (CNTR APT) foi utilizado para comparar a especificidade dos aptâmeros ligados a células viáveis, mostrando a não ligação deste aptâmero a MSC. Porém, 40% da população de monócitos ligou-se ao CNTR APT. Uma normalização baseada na comparação entre as taxas de ligação entre células ligadas com aptâmeros candidatos e o aptâmero controle gerou uma taxa de especificidade entre 10-16 vezes maior para MSC contra 2,5 vezes para os monócitos. Deste modo, embora os resultados tenham mostrado uma taxa de ligação entre monócitos e aptâmeros, as MSC ligadas aos aptâmeros candidatos possuem uma maior taxa de especificidade devido a uma maior presença de antígenos que são expressos em ambas as células. Um ensaio de Pull Down seguido de espectrometria de massas foi utilizado para a identificação de biomarcadores que se ligariam aos aptâmeros candidatos, e que não seriam co-expressos por monócitos e por antígenos ligados ao aptâmero controle. Deste modo, a proteína ADAM17 foi identificada nas amostras de APT10 ligadas às MSC. Tal proteína está relacionada à inibição de uma cascata de sinalização da família de proteínas TGF, responsável pela diferenciação de MSC. Assim, MSC com maior potencial tronco deveriam expressar ADAM17 em maior quantidade. Tal proteína apresenta um sítio catalítico que demonstra interagir com o APT10, de acordo com predição Docking entre proteína e DNA. Foi identificada também, a proteína VAMP3, que pertence a um complexo proteico transmembranar responsável pelos processos de endocitose e exocitose, e que podem ter um papel importante na liberação de citocinas e outras moléculas relacionadas às respostas imune e inflamatórias. Deste modo, o APT10 identificou proteínas importantes que devem estar relacionas com a melhora de imunoterapias que utilizam MSC

Los aptámeros como novedosa herramienta diagnóstica y terapéutica y su potencial uso en parasitología / Aptamers as a novel diagnostic and therapeutic tool and their potential use in parasitology

Los aptámeros son secuencias de ADN o ARN de cadena sencilla que adoptan la forma de estructuras tridimensionales únicas, lo cual les permite reconocer un blanco específico con gran afinidad. Sus usos potenciales abarcan, entre otros, el diagnóstico de enfermedades, el desarrollo de nuevos agentes terapéuticos, la detección de riesgos alimentarios, la producción de biosensores, la detección de toxinas, el transporte de fármacos en el organismo y la señalización de nanopartículas. El pegaptanib es el único aptámero aprobado para uso comercial por la Food and Drug Administration (FDA). Otros aptámeros para el tratamiento de enfermedades están en la fase clínica de desarrollo. En parasitología, se destacan los estudios que se vienen realizando en Leishmania spp., con la obtención de aptámeros que reconocen la proteína de unión a poliA (LiPABP) y que pueden tener potencial utilidad en la investigación, el diagnóstico y el tratamiento de la leishmaniasis. En cuanto a la malaria, se han obtenido aptámeros que permiten identificar eritrocitos infectados e inhiben la formación de rosetas, y otros que prometen ser alternativas para el diagnóstico al detectar de forma específica la proteína lactato deshidrogenasa (PfLDH). Para Cryptosporidium parvuum se han seleccionado aptámeros que detectan ooquistes a partir de alimentos o aguas contaminadas. Para Entamoeba histolytica se han aislado dos aptámeros llamados C4 y C5, que inhiben la proliferación in vitro de los trofozoítos y tienen potencial terapéutico. Los aptámeros contra Trypanosoma cruzi inhiben la invasión de células LLC-MK2 (de riñón de mono) en un 50 a 70 % y aquellos contra T. brucei transportan moléculas tóxicas al lisosoma parasitario como una novedosa estrategia terapéutica. Los datos recopilados en esta revisión destacan los aptámeros como una alternativa para la investigación, el diagnóstico y el tratamiento contra parásitos de interés nacional.

Aptamers are single-stranded DNA or RNA sequences that adopt unique three-dimensional structures that allow them to recognize a specific target with high affinity. They can potentially be used for the diagnosis of diseases, as new therapeutic agents, for the detection of food risks, as biosensors, for the detection of toxins, and as drug carriers and nanoparticle markers, among other applications. To date, an aptamer called pegaptanib is the only aptamer approved by the Food and Drug Administration (FDA) for commercial use. Other aptamers are in different clinical stages of development for the treatment of different diseases. In parasitology, investigations carried out with parasites such as Leishmania spp. allowed the acquisition of aptamers that recognize the polyA-binding protein LiPABP and may have potential applications in research and diagnosis and even as therapeutic agents. Regarding malaria, aptamers have been obtained that allow the identification of infected erythrocytes or inhibit the formation of rosettes, along with those that provide promising alternatives for diagnosis by specifically detecting the protein lactate dehydrogenase (PfLDH). In Cryptosporidium parvum allow the detection of oocysts in contaminated food or water. In Entamoeba histolytica, two aptamers called C4 and C5, which inhibit the proliferation of trophozoites in vitro and have potential use as therapeutic agents, have been isolated. Aptamers obtained against Trypanosoma cruzi inhibit the invasion of LLC-MK2 (from monkey kidney) cells by 50-70%, and in T. brucei, aptamers with the potential to transport toxic molecules to the parasitic lysosome were identified as a novel therapeutic strategy. The data collected in this review highlight aptamers as a novel alternative in the research, diagnosis, and treatment of parasites of national interest.

Research advances in the role of aptamers in the diagnosis and targeted therapy of pediatric cancer / 中国当代儿科杂志

Aptamers are single-stranded DNA or RNA which are isolated from synthesized random oligonucleotide library in vitro via systematic evolution of ligands by exponential enrichment (SELEX) and can bind to metal ions, small molecules, carbohydrates, lipids, proteins, and others targets with high affinity and specificity. Aptamers have the advantages of simple preparation, good thermal stability, and low immunogenicity and have great potential in the medical fields such as molecular imaging, biosensing, early diagnosis of diseases, and targeted therapy. Aptamer technology may be useful for early diagnosis and targeted therapy of pediatric cancer, and may avoid the side effects of conventional chemotherapy, such as growth and development disorders and long-term organ dysfunction. This article reviews the latest research advances in the selection and application of aptamers for pediatric cancer.

Development of a DNA aptamer for screening neisseria meningitidis serogroup B by cell SELEX

Background: Artificial oligonucleotides like DNA or RNA aptamers can be used as biodiagnostic alternatives for antibodies to detect pathogens. Comparing to antibodies, artificial oligonucleotides are produced easily at lower costs and are more stable. Neisseria meningitidis, the causative agent of meningitis, is responsible for about 1% of infections in an epidemic period. Specific DNA aptamers that bind to N. meningitidis serogroup B were identified by whole-cell Systemic Evolution of Ligands by EXponential Enrichment [SELEX]

Methods: The SELEX begins with a library of labeled ssDNA molecules. After six rounds of selection and two rounds of counter-selection, 60 clones were obtained, of which the binding efficiency of 21 aptamers to the aforementioned bacterium was tested by flow cytometry

Results: The aptamers K3 and K4 showed the highest affinity to N. meningitidis serogroup B and no affinity to N. meningitidis serogroups Y, A, and C, or to other meningitis causing bacteria. The dissociation constant [Kd value] for K3 and K4 were calculated as 28.3 +/- 8.9 pM and 39.1 +/- 8.6 pM, respectively. K3 aptamer with the lowest Kd was chosen as the main aptamer. K3 could detect N. meningitidis in patients' cerebrospinal fluid [CSF] samples and in CSF from healthy volunteers inoculated with N. meningitidis serogroup B [ATCC 13090] at 200 and 100 CFU ml[-1], respectively

Conclusion: The findings suggest the application of the developed aptamer in specific detection of N. meningitidis serogroup B amongst a group of meningitis causing bacteria

Real-time PCR: an appropriate approach to confirm ssDNA generation from PCR product in SELEX process

Background: Aptamers are single stranded DNA [ssDNA] or RNA molecules. The potential of aptamers for binding to the different targets has made them be widely used as the preferred diagnostic and therapeutic tools. DNA aptamers present several advantages over the RNA oligonucleotides due to their higher stability, easier selection, and production. Selection of DNA aptamers which is facilitated through a systematic evolution of ligand by exponential enrichment [SELEX] method is much dependent on the successful conversion of double stranded DNA [dsDNA] to ssDNA

Objective: There are different methods available for ssDNA generation. While visualization of ssDNA is limited to the gelbased method, the method is not applicable in the initial rounds of SELEX due to more than 1015 different sequences. This study was designed to evaluate the efficiency of another technique for confirming the ssDNA generation in comparison to the polyacrylamide electrophoresis [PAGE] analysis

Materials and Methods: Real-time PCR was employed in the present study for PCR amplification of the initial library that was followed by enzymatic digestion of the dsDNA. Subsequently melting curve analysis was carried out to evaluate ssDNA generation from dsDNA. Moreover, PAGE analysis was performed and the results were compared with the melt curve analysis

Results: The melt curves, revealed dsDNA conversion to the ssDNA based on a significant reduction of Tm from 73.8 to 41.5 [degree]C. Applying PAGE analysis, it was not effectively feasible to show ssDNA generation from the corresponding initial dsDNA library, while, it was efficient enough to confirm ssDNA generation in accordance with the increasing the number of SELEX rounds

Conclusion: The present study has proven the applicability of the real-time PCR as a suitable confirmatory technique for validating ssDNA generation in the DNA aptamer selection process for the initial library preparation

Aptamers as a promising approach for the control of parasitic diseases

ABSTRACT Aptamers are short single-stranded RNA or DNA oligonucleotides that are capable of binding various biological targets with high affinity and specificity. Their identification initially relies on a molecular process named SELEX (Systematic Evolution of Ligands by EXponential enrichment) that has been later modified in order to improve aptamer sensitivity, minimize duration and cost of the assay, as well as increase target types. Several biochemical modifications can help to enhance aptamer stability without affecting significantly target interaction. As a result, aptamers have generated a large interest as promising tools to compete with monoclonal antibodies for detection and inhibition of specific markers of human diseases. One aptamer-based drug is currently authorized and several others are being clinically evaluated. Despite advances in the knowledge of parasite biology and host-parasite interactions from "omics" data, protozoan parasites still affect millions of people around the world and there is an urgent need for drug target discovery and novel therapeutic concepts. In this context, aptamers represent promising tools for pathogen identification and control. Recent studies have reported the identification of "aptasensors" for parasite diagnosis, and "intramers" targeting intracellular proteins. Here we discuss various strategies that have been employed for intracellular expression of aptamers and expansion of their possible application, and propose that they may be suitable for the clinical use of aptamers in parasitic infections.

Aptamer–nanoparticle complexes as powerful diagnostic and therapeutic tools

Correct diagnosis and successful therapy are extremely important to enjoy a healthy life when suffering from a disease. To achieve these aims, various cutting-edge technologies have been designed and fabricated to diagnose and treat specific diseases. Among these technologies, aptamer–nanomaterial hybrids have received considerable attention from scientists and doctors because they have numerous advantages over other methods, such as good biocompatibility, low immunogenicity and controllable selectivity. In particular, aptamers, oligonucleic acids or peptides that bind to a specific target molecule, are regarded as outstanding biomolecules. In this review, several screening techniques for aptamers, also called systematic evolution of ligands by exponential enrichment (SELEX) methods, are introduced, and diagnostic and therapeutic aptamer applications are also presented. Furthermore, we describe diverse aptamer–nanomaterial conjugate designs and their applications for diagnosis and therapy.

Screening specific recognition motif of RNA-binding proteins by SELEX in combination with next-generation sequencing technique / 生物工程学报

RNA-binding protein exerts important biological function by specifically recognizing RNA motif. SELEX (Systematic evolution of ligands by exponential enrichment), an in vitro selection method, can obtain consensus motif with high-affinity and specificity for many target molecules from DNA or RNA libraries. Here, we combined SELEX with next-generation sequencing to study the protein-RNA interaction in vitro. A pool of RNAs with 20 bp random sequences were transcribed by T7 promoter, and target protein was inserted into plasmid containing SBP-tag, which can be captured by streptavidin beads. Through only one cycle, the specific RNA motif can be obtained, which dramatically improved the selection efficiency. Using this method, we found that human hnRNP A1 RRMs domain (UP1 domain) bound RNA motifs containing AGG and AG sequences. The EMSA experiment indicated that hnRNP A1 RRMs could bind the obtained RNA motif. Taken together, this method provides a rapid and effective method to study the RNA binding specificity of proteins.

Metabolismo de triptofano em melanomas: o que dizem as células do microambiente? / Tryptophan metabolism in melanomas: what do microenvironment cells can say?

O melanoma é composto por células malignas e também por um estroma de sustentação que inclui fibroblastos, células imunológicas, endoteliais, matriz extracelular, dentre outros fatores. Assim, os tumores não são entidades independentes, eles interagem ativamente com o microambiente adjacente de forma bidirecional através de sinais moleculares que modulam o fenótipo maligno. Um dos sinais bioquímicos para desenvolvimento desse fenótipo se dá pelo catabolismo de Trp pela via das quinureninas, que gera compostos com diversas atividades biológicas, que no tumor estão envolvidas com tolerância e imunoescape e, logo, com prognóstico ruim para os pacientes. Até o presente momento apenas o consumo de Trp e a formação de um único metabólito, a quinurenina (KYN), tem sido associada a malignidade dos melanomas. A fim de ampliar e elucidar os mecanismos bioquímicos do metabolismo desse aminoácido em melanomas, estudamos mais de quinze compostos de todas as rotas catabólicas de Trp em células da pele, células imunológicas, linhagens tumorais e amostras clínicas de melanoma. De forma inédita pudemos observar que as células da pele tem maior habilidade de sintetizar KYN quando comparadas às linhagens tumorais, demonstrando que o catabolismo de Trp peritumoral pode ser responsável pelos fenômenos de imunotolerância e escape. Além disso, o metabolismo de Trp pode estar envolvido nos mecanismos de homeostasia da pele, já que especificamente essas células produzem compostos com atividade biológica nesse órgão. As células imunológicas possuem um perfil metabólico completamente diferente umas das outras: monócitos, macrófagos e dendríticas possuem maior ativação da via KYN enquanto linfócitos e neutrófilos possuem maior indução da rota que gera serotonina e melatonina. Mesmo nos diferentes fenótipos de macrófagos, M1 e M2a, foram observadas marcações especificas de metabolismo, que podem estar relacionadas às atividades anti- ou pró-tumoral dessas células no microambiente. Em amostras clínicas, apesar da principal diferença entre nevos e melanomas ser a concentração de KYN, diversas outras alterações no metabolismo de tiptofano foram observadas, o que mostra a complexa magnitude deste metabolismo na fisiopatologia da pele

Melanoma is composed of malignant cells and also by a stromal support that includes fibroblasts, immune cells, endothelial cells, extracellular matrix, among other factors. Thus, tumors are not separate entities; they actively interact with the surrounding microenvironment bi-directionally through molecular signals that modulate the malignant phenotype. One of biochemical signals for the development of this phenotype occurs by Trp catabolism through kynurenine pathway, that generates compounds with diverse biological activities, which in tumors are involved with tolerance and imunoescape and therefore with poor prognosis for patients. To date only the consumption of Trp and formation of a single metabolite, kynurenine (KYN), has been associated with malignant melanomas. In order to enlarge and clarify the biochemical mechanisms of this amino acid metabolism in melanomas, we have studied more than fifteen compounds of all catabolic routes of Trp in skin cells, immune cells, tumor cell lines and clinical samples of melanoma. In an unique way we could observe that the skin cells has superior ability to synthesize KYN when compared to tumor cell lines, demonstrating that the peritumoral catabolism of Trp may be responsible for the phenomena of immune tolerance and escape. Furthermore, the Trp metabolism may be involved in skin homeostasis mechanisms, since these cells produce specific compounds with biological activity in this organ. The immune cells have a completely different metabolic profile among them: monocytes, macrophages and dendritic cells have greater KYN pathway activation, and lymphocytes and neutrophils possess greater induction of the route that generates serotonin and melatonin. Even in different macrophages phenotypes, M1 and M2a, we observed specific metabolic marks, which may be related to the anti- or pro-tumoral activity of these cells in the tumor microenvironment. In clinical samples, although the main difference between nevi and melanomas is the concentration of KYN, a range of other changes in Trp metabolism were observed, which shows the complex magnitude of this metabolism in the skin pathophysiology

DNA aptamer selection in vitro for determining ketamine by FluMag-SELEX / 法医学杂志

OBJECTIVE@#To select specific DNA aptamer for determining ketamine by FluMag-SELEX.@*METHODS@#Based on magnetic beads with tosyl surface modification as solid carrier and ketamine as target, a random ssDNA library with total length of 78 bp in vitro was compounded. After 13 rounds screening, DNA cloning and sequencing were done. Primary and secondary, structures were analyzed. The affinity, specificity and Kd values of selected aptamer were measured by monitoring the fluorescence intensity.@*RESULTS@#Two ssDNA aptamers (Apt#4 and Apt#8) were successfully selected with high and specific abilities to bind ketamine as target with Kd value of 0.59 and 0.66 μmol/L. The prediction of secondary structure was main stem-loop and G-tetramer. The stem was the basis of stability of aptamer's structure. And loop and G-tetramer was the key of specific binding of ketamine.@*CONCLUSION@#FluMag-SELEX can greatly improve the selection efficiency of the aptamer, obtain the ketamine-binding DNA aptamer, and develop a new method for rapid detection of ketamine.

Seleção de aptâmeros que se ligam ao receptor humano para o gosto doce / Screening for aptamers that bind to the human sweet taste receptor (hT1R2/hT1R3)

Foi demonstrado que o gosto doce é transduzido por receptores acoplados a proteína G classe III (GPCRs), T1R2 e T1R3. Essas proteínas exibem longas extremidades amino-terminais que formam um domínio de ligação globular extracelular. Elas são expressas em células associadas ao gosto (células epiteliais que constituem os botões gustativos nas papilas gustativas), que respondem a moléculas associadas ao gosto doce. Quando T1R2 e T1R3 são co-expressas em células heterólogas, elas respondem, como heterômeros, a uma série de açúcares, alguns D-aminoácidos, edulcorantes artificiais e proteínas doces. Foi também demonstrado que o receptor humano T1R2/T1R3 para o gosto doce apresenta múltiplos sítios de ligação. Para melhor compreender a estrutura desse receptor e responder à pergunta de como um único quimiorreceptor pode ser responsivo a uma variedade de ligantes, foi utilizada a abordagem denominada evolução sistemática de ligantes por enriquecimento exponencial (SELEX) para isolar, a partir de uma biblioteca combinatória de oligonucleotídeos, aptâmeros de RNA resistentes a nuclease que se ligam ao receptor humano para o gosto doce com alta afinidade. Após um enriquecimento de doze ciclos do pool original de RNA contendo em torno de 1013 sequências diferentes (contra preparações de membrana de células HEK293T que expressam hT1R2/hT1R3) e outros ciclos de contrasseleção negativa (para eliminar moléculas de RNA que se ligam de forma inespecífica à membrana de nitrocelulose e a outras proteínas diferentes do alvo, ou seja, proteínas de membrana de células HEK293T selvagem), realizou-se a transcrição reversa do RNA seguida de amplificação por PCR e sequenciamento. Aptâmeros do ciclo 12 com sequências consenso foram selecionados, e a ligação de alguns deles com hT1R2/hT1R3 foi então avaliada. Cinco desses aptâmeros mostram claramente uma maior afinidade por células HEK293T que expressam hT1R2/hT1R3. Como segunda parte desta tese, estudamos outro receptor, denominado CD36, que, como o receptor T1R2/T1R3, é expresso na língua. Estudos indicam que ele age como receptor gustativo de gordura. Neste trabalho, verificamos que essa proteína é expressa em uma subpopulação de neurônios olfatórios presentes no epitélio olfatório, indicando que ela pode ter também uma função olfatória, ainda não caracterizada

It has been shown that sweet taste is transduced by the Class III G Protein-Coupled Receptors (GPCRs) T1R2 and T1R3, which show long N-termini that form a globular extracellular ligand-binding domain. These receptors are expressed in the taste cells (epithelial cells that constitute the taste buds in taste papillae) that respond to sweet tastants, and when T1R2 and T1R3 are coexpressed in heterologous cells, they respond, as heteromers, to a series of sugars, some D-amino acids, artificial sweeteners and sweet proteins. It has also been demonstrated that the sweet taste receptor has multiple binding sites. In order to better understand the structure of this receptor and answer the question of how a single chemoreceptor can respond to a variety of ligands, we used the combinatorial oligonucleotide library screening approach, denominated Systematic Evolution of Ligands by Exponential Enrichment (SELEX), to isolate nuclease-resistant RNA aptamers that bind to the human sweet taste receptor with high affinity. Following a twelve round enrichment of the previous random RNA pool containing around 1013 different sequences (against membrane preparations of hT1R2/hT1R3-expressing HEK293T cells) and negative counterselection cycles (to eliminate RNA molecules that bind nonspecifically to the nitrocellulose membrane and to proteins other than the target, that is, HEK293T cells membrane proteins), the RNA was reverse-transcribed for DNA sequencing. Aptamers from cycle 12 with consensus sequences were selected, and the binding of some of them to the human sweet taste receptor was then evaluated. Five out of the aptamers clearly show greater affinity for hT1R2/hT1R3-expressing HEK293T cells than for hT1R2/hT1R3-non-expressing HEK293T cells. In this thesis we have also analyzed another receptor, denominated CD36, which is also expressed in the tongue. Studies indicate that it acts as a receptor for fat. In this work, we found that CD36 is expressed in a subset of the olfactory neurons localized in the olfactory epithelium, indicating that it may also have an as yet uncharacterized olfactory function

Purificação de células troco de lipoaspirado humano por aptâmeros de DNA, seguida da caracterização dos fenótipos obtidos da diferenciação neuronal / Human adipose mesechymal stem cell separation by DNA aptamers followed by the characterization of the obtained phenotypes from neuronal differentiation

Células tronco mesenquimais de tecido adiposo, são uma promissora ferramenta para aplicações clínicas em terapias celular e regenerativa, em vista da facilidade de sua extração e da maior quantidade de células por unidade de massa de tecido quando comparado a outras fontes clássicas de células mesenquimais como medula óssea. O protocolo clássico de extração e purificação dessas células, depende de sua adesão em plástico e xeno-materiais demandando muito tempo para ser utilizado por médicos para auxiliar pacientes em procedimentos de emergência. Estas células são capazes se diferenciar em diversos tipos celulares, o que as torna boas candidatas para terapia celular, embora sua capacidade de transdiferenciação para fenótipos neuronais seja ainda discutida. Neste trabalho demonstramos um novo processo para isolar essas células na base de epitopos específicos expressos (assinatura molecular de superfície) utilizando aptâmeros como ligantes de alta afinidade para estes sitios. Aptâmeros, moléculas de DNA simples fita identificadas a partir de uma biblioteca combinatória de sequencias de DNA simples-fita foram identificados por ciclos reiterativos de seleção in vitro (SELEX) utilizando células tronco do lipoaspirado como alvo. Dois aptâmeros isolados, denominados APT9 e APT11, foram capazes de identificar subpopulações (15,8 e 23,7% respectivamente) dentre as células tronco mesenquimais (classicamente CD29+/CD90+/CD45-) e separá-las usando nano-partículas magnéticas acopladas aos aptâmeros. Além disso, seguindo uma indução para diferenciação neuronal, as células tronco mesenquimais passam a apresentar morfologia neuronal e apresentam expressão e atividade de diversos receptores de neurotransmissores, avaliados por PCR real-time e imageamento de variações da concentração de cálcio intracelular ápos stimulação com vários agonistas de receptores metatrópicos e ionotrópicos. Ao longo da diferenciação, os níveis transcricionais de mRNA de receptores de cininas (B1 e B2), nicotínicos (alfa 7), muscarínicos (M1, M3 e M4), glutamatérgicos (AMPA2 e mGluR2), purinérgicos (P2Y1 e P2Y4) e GABAergicos (GABA-A, subunidade 3) e da óxido nítrico sintase neural aumentaram quando comparados aos níveis das células não diferenciadas, enquanto que os níveis de expressão de outros receptores incluindo purinérgicos P2X1, P3X4, P2X7 e P2Y6 e muscarínico M5 diminuíram. Os níveis de atividade das classes dos receptores estudados, por imageamento de variações da concentração de cálcio intrac, aumentaram para a maioria dos agonistas analisados durante a diferenciação neuronal com exceção para respostas induzidas por glutamato e NMDA. Células diferenciadas expressavam altos níveis de antígenos específicos de neurônios como ß3-tubulina, NF-H, NeuN e MAP-2 indicando uma diferenciação em fenótipo neuronal bem sucedida. Desta maneira, esta tese, ao identificar aptâmeros, prove uma inovadora solução para médicos usarem as células tronco mesenquimais dentro de uma sala de cirurgia, através de um método que é capaz de purificar essas células em um tempo clínico viável, com pureza e sem contato com contaminantes. Além disso, nós mostramos aqui que com um protocolo como o proposto para diferenciação neuronal, nós poderíamos induzir essas células para se diferenciar em neurônios, através da ativação de fatores de transcrição específicos, levando às células tronco mesenquimais a serem possivelmente utilizadas em terapias celulares de reparo neuronal

Adipose mesenchymal stem cells are promising tools for clinical applications in cellular and regeneration therapies, in view of easiness of extraction and higher amount of isolated stem cells per mass of tissue when compared to other classical mesenchymal stem cell sources including bone marrow. The classical protocol to extract and purify these cells, depending on plastic adherence and xeno-materials, is too time consuming to be used by physicians to help patients at emergency procedures. These cells are able to differentiate into various cell types, making them good candidates for cell therapy, however their capability for transdifferentiation into neural phenotypes is yet discussed. Here we show a novel process to isolate these cells using their surface molecular signature and aptamers, ssDNA molecules identified through the SELEX technique, denominated APT9 and APT11 that are able to identify subpopulations (15,8 and 23,7% respectively) within the mesenchymal stem cells (classically CD29+/CD90+/CD45-) and separate them using magnetic nano-particles attached to the aptamers. Moreover, following induction to neural differentiation, mesenchymal cells presents neuronal morphology and present expression and activity of several neurotransmitter receptors, as evaluated by real-time PCR and calcium imaging. During this process, mRNA transcription levels of bradykinin (B1 and B2), cholinergic (alpha 7), muscarinic (M1, M3 and M4), glutamatergic (AMPA2 and mGlu2), purinergic (P2Y1 and P2Y4) and GABAergic (GABA-A, subunit 3) receptors and neuronal nitric oxide synthase were augmented when compared to levels of undifferentiated cells, while the expression levels of other receptors including purinergic P2X1, P2X4, P2X7 and P2Y6 and muscarinic M5 receptors were down-regulated. Activity levels of the studied receptor classes, as studied by calcium imaging, increased for most of the agonists analyzed during the neuronal differentiation with the exception for glutamate- and NMDA-induced receptor responses. Differentiated cells expressed high levels of neuron-specific antigens such as ß3-tubulin, NF-H, NeuN and MAP-2, indicating a successful differentiation into neuronal phenotypes. This thesis, by identifying aptamers, provides a novel solution for physicians to use mesenchymal stem cells inside a surgery room, by using a method that are able to purify the cells in a clinical viable time, with purity and no contact with contaminats. Furthermore, we show here that with a protocol as provided for neuronal differentiation, we could induce these cells to differentiate into neurons, by activating specific transcription factors,making mesenchymal stem cells to possibly be used in neuronal repair cell therapies

Recent progress on SELEX and its applications / 病毒学报

SELEX technology (Systematic Evolution of Ligand by Exponential Enrichment) is a new in vitro screening technology appeared and developed in the past 20 years. SELEX integrate library technology and screening techniques, screening a nucleic acid molecule from nucleic acid library by ligand-aptamer interaction. Similar to the antibodies, aptamers bind with the specific target substance. SELEX screening technology develops rapidly, and aptamer have been widely applied in biomedical field. This article briefly-overviewed the progress and its applications of SELEX technology in recent years.

Recent progress of the aptamer-based antiviral drugs / 药学学报

Aptamers are capable of binding a wide range of biomolecular targets with high affinity and specificity. It has been widely developed for diagnostic and therapeutic purposes. Because of unique three dimensional structures and cell-membrane penetration, aptamers inhibit virus infection not only through binding specific target, such as the viral envelope, genomic site, enzyme, or other viral components, but also can be connected to each other or with siRNA jointly achieve antiviral activity. Taking human immunodeficiency virus and hepatitis C virus as examples, this paper reviewed the effects and mechanisms of aptamers on disturbing viral infection and replication steps. It may provide an insight to the development of aptamer-based new antiviral drugs.

Cell-ELA-based determination of binding affinity of DNA aptamer against U87-EGFRvIII cell / 生物工程学报

A15, a DNA aptamer with binding specificity for U87 glioma cells stably overexpressing the epidermal growth factor receptor variant III (U87-EGFRvIII), was generated by cell systematic evolution of ligands by exponential enrichment (cell-SELEX) using a random nucleotide library. Subsequently, we established a cell enzyme-linked assay (cell-ELA) to detect the affinity of A15 compared to an EGFR antibody. We used A15 as a detection probe and cultured U87-EGFRvIII cells as targets. Our data indicate that the equilibrium dissociation constants (K(d)) for A15 were below 100 nmol/L and had similar affinity compared to an EGFR antibody for U87-EGFRvIII. We demonstrated that the cell-ELA was a useful method to determine the equilibrium dissociation constants (K(d)) of aptamers generated by cell-SELEX.

A novel SELEX method for screening of HIV-1 P24 antigen / 中华实验和临床病毒学杂志

<p><b>OBJECTIVE</b>To screen aptamers that can bind P24 antigen tightly and specificly, and verify its specificity and affinity.</p><p><b>METHODS</b>Polycarbonate PCR plate was coated with P24 antigen and SELEX technology was used to screen aptamer on the PCR plate. The primary and secondary structure of these aptamers was analyzed by software. Through HRP labeled streptavidin and biotin labeled aptamers, the affinity and specificity of obtained aptamers were verified by ELISA.</p><p><b>RESULTS</b>The polycarbonate PCR plate could be coated with P24 antigen. Electrophoretic analysis showed the aptamers had been enriched. Sequence aligment analysis showed that these aptamers have consensus sequence and their apatial structure was multiple; ELISA verified that aptamers had high affinity with P24 antigen.</p><p><b>CONCLUSION</b>A simple method was established for screening aptamers that can bind HIV-1 P24 antigen specificly and tightly.</p>

Selection and identification of ssDNA aptamers specific to clinical isolates of Streptococcus mutans strains with different cariogenicity / 南方医科大学学报

<p><b>OBJECTIVE</b>To select and identify ssDNA aptamers specific to Streptococcus mutans strains with different cariogenicity isolated from clinical specimens.</p><p><b>METHODS</b>Subtractive SELEX technology targeting the whole intact cells was used to screen for ssDNA aptamers specific to the clinical isolates Streptococcus mutans strains with different cariogenicity. Radioactive isotope, flow cytometry, gene cloning and sequencing, MEME online software and RNA structure analysis software were employed to analyze the first and secondary structures of the aptamers and identify the screened aptamers.</p><p><b>RESULTS</b>Detection by radioactive isotope showed sufficient pool enrichment after 9 rounds of subtractive SELEX. Flow cytometry showed that the selected aptamers H1, H16, H4, L1, L10 and H19 were capable of binding specifically with highly cariogenic Streptococcus mutans strains but not with strains with a low cariogenicity. The aptamer H19 had the strongest binding capacity to highly cariogenic Streptococcus mutans strains, with a dissociation constant of 69.45∓38.53 nmol/L.</p><p><b>CONCLUSION</b>We have obtained the ssDNA aptamers specific to the clinical isolates of highly cariogenic Streptococcus mutans strains.</p>

In vitro selection of single strand deoxyribonucleic acid aptamers binding to cells from patients with acute myeloblastic leukemia / 中南大学学报(医学版)

OBJECTIVE@#To screen aptamers binding CD33+/CD34- cells from patients with acute myeloblastic leukemia M2 subtype (AML-M2).@*METHODS@#CD33+/CD34- cells from patients with AML-M2 were taken as targeted cells, CD33+/ CD34- cells from normal people were taken as anti-selecting cells, and aptamers in the single strand deoxyribonucleic acid (ssDNA) library were then selected repeatedly by cell-systematic evolution of ligands by exponential enrichment (C-SELEX) technology, and amplified by polymerase chain reaction (PCR) to generate sub-ssDNA library. During the experiment, PCR amplification with fluorescently labeled primer and flow cytometry were performed to analyze the aptamers'enrichment of sub-library, and the final round product of the sub-ssDNA library was cloned. After the sequencing, the primary and secondary structures of the aptamers were analyzed.@*RESULTS@#Electrophoresis indicated that the product of PCR amplification for each round subssDNA library was able to see a clear DNA band in the agarose gel. After 13 rounds of screening, the fluorescence intensity of the sub-ssDNA library binding the cells ranged from 2.14% to 51.12%, reaching a steady state at the 13th round. A total of 30 clones were selected and sequenced, 22 of which contained 1 of the 4 conserved sequences of AAGTA, TATCT, AGATG and AAATT in their primary structure, but the remained eight aptamers contained none of the conserved sequence. Secondary structure analysis indicated that four stem-loops and loop simulation convex structures existed in the aptamers.@*CONCLUSION@#C-SELEX technology can be used to screen the aptamers binding primary cells from patients with leukemia. The aptamers selected from the CD33+/CD34- cells from the patients of AML-M2 subtype might be used for the diagnosis and treatment for leukemia.

Screening and characterization of aptamers of Cepsilon3-Cepsilon4 protein / 药学学报

In order to obtain nucleotides aptamers bind to IgE, 80 bp nucleotides single-stranded DNA library containing 40 random nucleotides was designed and synthesized. Oligonucleotides that bind to human Cepsilon3-Cepsilon4 protein were isolated from ssDNA pools by the systematic evolution of ligands by exponential enrichment (SELEX) method using nitrocellulose filters as screening medium. Through the optimization of critical PCR and asymmetric PCR parameters including annealing temperature, cycles, and molar ratios of target protein and ssDNA etc, a suitable screening system was established. The aptamers of Cepsilon3-Cepsilon4 protein with high affinity and high specificity were identified by ELISA with biotin-streptavidin-horseradish peroxidase system, and its primary sequence and second structure were analyzed by DNAMAN package and DNA folding sever after being cloned and sequenced. Moreover, target protein was bound to one aptamer and another aptamer modified with biotion together forming a sandwich-like complex, which was captured in microwell to detect IgE concentration using the optimal combination in the sandwich method named enzyme-linked aptamers sorption assay (ELASA). The method could be used for the quantitative detection of human IgE, and whose sensitivity reached to 120 ng x mL(-1).