Aptamer-based cell-free detection system to detect target protein

Chen, Junhong; Zhuang, Xinbo; Zheng, Jiyang; Yang, Ruofan; Wu, Fei; Zhang, Aihui; Fang, Baishan

doi:10.1016/j.synbio.2021.07.004

Cited by 10 publications

(3 citation statements)

References 35 publications

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“…Organisms have evolved a large number of proteins to perform different physiological functions (Chen et al, 2021). In this study, the intracellular proteins, except PNP1, UP and some proteins that affect bacterial growth were all defined as UNPs.…”

Section: Proteomic Analysismentioning

confidence: 99%

Whole‐cell biosynthesis of cytarabine by an unnecessary protein‐reduced Escherichia coli that coexpresses purine and uracil phosphorylase

Ping

Ruxian

Mengping

et al. 2022

Biotech & Bioengineering

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Currently, whole-cell catalysts face challenges due to the complexity of reaction systems, although they have a cost advantage over pure enzymes. In this study, cytarabine was synthesized by purified purine phosphorylase 1 (PNP1) and uracil phosphorylase (UP), and the conversion of cytarabine from adenine arabinoside reached 72.3 ± 4.3%. However, the synthesis was unsuccessful by whole-cell catalysis due to interference from unnecessary proteins (UNPs) in cells. Thus, we carried out a large-scale gene editing involving 377 genes in the genome of Escherichia coli to reduce the negative effect of UNPs on substrate conversion and cytarabine production. Finally, the PNP1 and UP activities of the obtained mutant were increased significantly compared with the parental strain, and more importantly, the conversion rate of cytarabine by whole-cell catalysis reached 67.4 ± 2.5%. The lack of 148 proteins and downregulation of 783 proteins caused by gene editing were equivalent to partial purification of the enzymes within cells, and thus, we provided inspiration to solve the problem caused by UNP interference, which is ubiquitous in the field of whole-cell catalysis.

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Section: Proteomic Analysismentioning

confidence: 99%

Whole‐cell biosynthesis of cytarabine by an unnecessary protein‐reduced Escherichia coli that coexpresses purine and uracil phosphorylase

Ping

Ruxian

Mengping

et al. 2022

Biotech & Bioengineering

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“…Selective detection of proteins is of paramount importance in clinical diagnostics and therapeutics . Protein detections are carried out in a wide variety of ways that are based on specific recognition of biomarkers using specific antibodies or aptamers, gel electrophoresis, surface-enhanced laser desorption–ionization mass spectrometry, and so on. − While fluorescent or chemiluminescent labeled specific antibodies are commonly utilized in sensitive protein detection methods, their high fabrication cost poses significant constraints on their widespread applications. Recent advancements have focused on the development of aptamer-based fluorescent and electrochemical methods for protein detection. − Yet, finding specific aptamers for each protein analyte remains a formidable and time-consuming challenge.…”

Section: Introductionmentioning

confidence: 99%

Dual Optical Response Strategy for the Detection of Cytochrome c Using Highly Luminescent Lanthanide-Based Nanotubular Sensor Arrays

Kamalakshan,

Jamuna,

Chittilappilly Devassy

et al. 2024

ACS Appl. Bio Mater.

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Here, we demonstrate a label-free dual optical response strategy for the detection of cytochrome c (Cyt c) with ultrahigh sensitivity using highly luminescent lanthanides containing inorganic−organic hybrid nanotubular sensor arrays. These sensor arrays are formed by the sequential incorporation of the photosensitizers 2,3-dihydroxynaphthalene (DHN) or 1,10-phenanthroline (Phen), and trivalent lanthanide terbium ions (Tb 3+ ) into sodium lithocholate (NaLC) nanotube templates. Our sensing platform relies on the detection and quantification of Cyt c in solution by providing dual photoluminescence quenching responses from the nanotubular hybrid arrays in the presence of Cyt c. The large quenching of the sensitized Tb 3+ emission within the DHN/Phen-Tb 3+ -NaLC nanotubular sensor arrays caused by the strong binding of the photosensitizers to Cyt c provides an important signal response for the selective detection of Cyt c. This long-lived lanthanide emission response-based sensing strategy can be highly advantageous for the detection of Cyt c in a cellular environment eliminating background fluorescence and scattering signals through time-gated measurements. The DHN containing nanotubular sensor arrays (DHN-NaLC and DHN-Tb 3+ -NaLC) provide an additional quenching response characterized by a unique spectral valley splitting with quantized quenching dip on the DHN fluorescence emission. This spectral quenching dip resulting from efficient FRET between the protein bound DHN photosensitizer and the heme group of Cyt c serves as an important means for specific detection and quantification of Cyt c in the concentration range of 0−30 μM with a low detection limit of around 20 nM.

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“…They usually range from 20 to 60 nucleotides that can fold into a unique three-dimensional (3D) conformation so that they can bind to their targets [ 30 ]. They can specifically bind to a wide range of ligand targets, from simple inorganic molecules [ 31 ] that antibodies cannot recognize to large protein complexes [ 32 ] and cells [ 33 ]. Aptamers are actually nucleotide analogues to antibodies with much more advantages.…”

Section: Introductionmentioning

confidence: 99%

Generation and Selection of Specific Aptamers Targeting Brucella Species through an Enhanced Cell-SELEX Methodology

El-Husseini

Sayour

Melzer

et al. 2022

IJMS

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Brucellae are Gram-negative, aerobic, non-motile coccobacilli causing brucellosis in man and animals. The disease is one of the most significant yet neglected global zoonoses. Especially in developing countries, brucellosis is causing public health problems and economic losses to private animal owners and national revenues. Composed of oligonucleotides, aptamers are chemical analogues of antibodies that are promising components for developing aptamer-based rapid, sensitive, and specific tests to identify the Brucella group of bacteria. For this purpose, aptamers were generated and selected by an enhanced protocol of cell systematic evolution of ligands by exponential enrichment (cell-SELEX). This enhanced cell-SELEX procedure involved the combination of both conventional and toggle cell-SELEX to boost the specificity and binding affinity to whole Brucella cells. This procedure, combined with high-throughput sequencing of the resulting aptamer pools, comprehensive bioinformatics analysis, and wet lab validation assays, led to the selection of a highly sensitive and specific aptamer for those Brucella species known to circulate in Egypt. The isolated candidate aptamer showed dissociation constant (KD) values of 43.5 ± 11, 61.5 ± 8, and 56 ± 10.8 nM for B. melitensis, B. abortus, and B. suis, respectively. This is the first development of a Brucella-specific aptamer using an enhanced combination of conventional and toggle cell-SELEX to the authors’ best knowledge.

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Aptamer-based cell-free detection system to detect target protein

Cited by 10 publications

References 35 publications

Whole‐cell biosynthesis of cytarabine by an unnecessary protein‐reduced Escherichia coli that coexpresses purine and uracil phosphorylase

Whole‐cell biosynthesis of cytarabine by an unnecessary protein‐reduced Escherichia coli that coexpresses purine and uracil phosphorylase

Dual Optical Response Strategy for the Detection of Cytochrome c Using Highly Luminescent Lanthanide-Based Nanotubular Sensor Arrays

Generation and Selection of Specific Aptamers Targeting Brucella Species through an Enhanced Cell-SELEX Methodology

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