Photocaged functional nucleic acids for spatiotemporal imaging in biology

Imaging of species in living organisms with high spatiotemporal resolution is essential for understanding biological processes. While functional nucleic acids (FNAs), such as catalytic nucleic acids and aptamers, have emerged as effective sensors for a wide range of molecules, photocaged control of these FNAs has played a key role in translating them into bioimaging agents with high spatiotemporal control. In this review, we summarize methods and results of photocaged FNAs based on photolabile modifications, photoisomerization, and photothermal activation. Future directions, including strategies to improve the performance of these photocaged FNAs, are also described.     

基于核酸适配体的生物分析新方法研究进展

核酸适配体是从随机文库中采用SELEX技术筛选所得的单链短链寡核苷酸片段(通常为15-80个ss DNA或ss RNA)。其能够折叠形成独特稳定的三维结构,通过静电相互作用,氢键,范德华力,碱堆叠或多种作用力组合特异性地与多种靶标结合。适配体因具有构象变化能力而被用作生物分析中的理想识别配体。目前,基于适配体的生物分析新方法得到广泛研究,并用于蛋白多肽类药物分析、疾病标志物诊断、外泌体检测、循环肿瘤细胞检测和病毒检测等方面。本文综述了核酸适配体用于生物分析方法开发的最新进展,比较和讨论不同分析方法,并对基于适配体的生物分析新方法提出了设想和展望,为开发新的生物分析方法和检测技术提供了思路和借鉴。     

Evolutionary Landscapes for the Acquisition of New Ligand Recognition by RNA Aptamers

The evolution of ligand specificity underlies many important problems in biology, from the appearance of drug resistant pathogens to the re-engineering of substrate specificity in enzymes. In studying biomolecules, however, the contributions of macromolecular sequence to binding specificity can be obscured by other selection pressures critical to bioactivity. Evolution of ligand specificity in vitro—unconstrained by confounding biological factors—is addressed here using variants of three flavin-binding RNA aptamers. Mutagenized pools based on the three aptamers were combined and allowed to compete during in vitro selection for GMP-binding activity. The sequences of the resulting selection isolates were diverse, even though most were derived from the same flavin-binding parent. Individual GMP aptamers differed from the parental flavin aptamers by 7 to 26 mutations (20 to 57% overall change). Acquisition of GMP recognition coincided with the loss of FAD (flavin-adenine dinucleotide) recognition in all isolates, despite the absence of a counter-selection to remove FAD-binding RNAs. To examine more precisely the proximity of these two activities within a defined sequence space, the complete set of all intermediate sequences between an FAD-binding aptamer and a GMP-binding aptamer were synthesized and assayed for activity. For this set of sequences, we observe a portion of a neutral network for FAD-binding function separated from GMP-binding function by a distance of three mutations. Furthermore, enzymatic probing of these aptamers revealed gross structural remodeling of the RNA coincident with the switch in ligand recognition. The capacity for neutral drift along an FAD-binding network in such close approach to RNAs with GMP-binding activity illustrates the degree of phenotypic buffering available to a set of closely related RNA sequences—defined as the sets functional tolerance for point mutations—and supports neutral evolutionary theory by demonstrating the facility with which a new phenotype becomes accessible as that buffering threshold is crossed.     

In vitro evolution of RNA aptamers recognizing carcinogenic aromatic amines

The modification of cellular DNA by environmental substances is thought to be a crucial event in chemical induced carcinogenesis. Among the environmental carcinogens, aromatic amines are known for the fact that they can induce several types of cancers through the formation of so-called DNA adducts. We took advantage of the potential of the SELEX method to select for highly specific RNA ligands that recognize specific genotoxic aromatic amines. The aromatic amine 4,4'-methylenedianiline (MDA) was used as a target. Following in vitro selection, we obtained specific MDA-binding RNA molecules based on an affinity chromatography assay. These results open the possibility of using the SELEX technique to generate RNA molecules as diagnostic tools for the detection of DNA damaging compounds and ultimately DNA adducts.     

Assays for cytokines using aptamers

Aptamers are short nucleic acid sequences that are used as ligands to bind their targets with high affinity. They are generated via the combinatorial chemistry procedure systematic evolution of ligands by exponential enrichment (SELEX). Aptamers have shown much promise towards detection of a variety of protein targets, including cytokines. Specifically, for the determination of cytokines and growth factors, several assays making use of aptamers have been developed, including aptamer-based enzyme-linked immunosorbent assays, antibody-linked oligonucleotide assay, fluorescence (anisotropy and resonance energy transfer) assays, and proximity ligation assays. In this article, the concept of aptamer selection using SELEX and the assay formats using aptamers for the detection of cytokines are discussed.     

NOVEL DNA NANOPARTICLES AND NETWORKS

Joining the thrombin-binding aptamer 5′-d(GGTTGGTGTGGTTGG) and the minihairpin 5′-d(GCGAAGC) leads to new DNA nanoparticles, which are different from rod-like helical double-stranded DNA. Covalent interstrand cross-links in DNA duplexes generated by bifunctional alkadiyne chains were used to build-up the DNA networks.     

A novel lipopolysaccharide-antagonizing aptamer protects mice against endotoxemia

A growing number of researchers have recognized the importance of using lipopolysaccharide (LPS) as target for the prevention and treatment of sepsis. However, no drugs targeting LPS have been applied clinically. In this study, LPS-inhibiting aptamers were screened by Systematic Evolution of Ligands by Exponential Enrichment (SELEX), and their therapeutic effects for experimental sepsis were observed. After 12 rounds of screening, 46 sequences were obtained. Primary structure analysis indicated that they had identical sequences, partly conserved sequences, or non-conserved sequences. Secondary structure analysis showed these sequences usually contained hairpin or stem-loop structures. Aptamer 19 significantly decreased NF-κB activation of monocytes challenged by LPS and reduced the IL-1 and TNF-α concentration in the media of LPS-challenged monocytes. Furthermore, aptamer 19 significantly increased the survival rate of mice with endotoxemia. The results suggest that a novel LPS antagonizing aptamer was obtained by SELEX, which successfully treated experimental sepsis.     

Detection technologies for Bacillus anthracis: Prospects and challenges

Bacillus anthracis is a Gram-positive, spore-forming bacterium representing the etiological agent of acute infectious disease anthrax, a lethal but rare disease of animals and humans in nature. With recent use of anthrax as a bioweapon, a number of techniques have been recently developed and evaluated to facilitate its rapid detection of B. anthracis in the environment as well as in point-of-care settings for humans suspected of exposure to the pathogen. Complex laboratory methods for B. anthracis identification are required since B. anthracis has similarities with other Bacillus species and its existence in both spore and vegetative forms. This review discusses current challenges and various improvements associated with anthrax agent detection.     

Time-resolved measurements of intracellular ATP in the yeast Saccharomyces cerevisiae using a new type of nanobiosensor

Adenosine 5'-triphosphate is a universal molecule in all living cells, where it functions in bioenergetics and cell signaling. To understand how the concentration of ATP is regulated by cell metabolism and in turn how it regulates the activities of enzymes in the cell it would be beneficial if we could measure ATP concentration in the intact cell in real time. Using a novel aptamer-based ATP nanosensor, which can readily monitor intracellular ATP in eukaryotic cells with a time resolution of seconds, we have performed the first on-line measurements of the intracellular concentration of ATP in the yeast Saccharomyces cerevisiae. These ATP measurements show that the ATP concentration in the yeast cell is not stationary. In addition to an oscillating ATP concentration, we also observe that the concentration is high in the starved cells and starts to decrease when glycolysis is induced. The decrease in ATP concentration is shown to be caused by the activity of membrane-bound ATPases such as the mitochondrial F(0)F(1) ATPase-hydrolyzing ATP and the plasma membrane ATPase (PMA1). The activity of these two ATPases are under strict control by the glucose concentration in the cell. Finally, the measurements of intracellular ATP suggest that 2-deoxyglucose (2-DG) may have more complex function than just a catabolic block. Surprisingly, addition of 2-DG induces only a moderate decline in ATP. Furthermore, our results suggest that 2-DG may inhibit the activation of PMA1 after addition of glucose.