GVARJALADZE, David, Tamari GULUA, Shota GOGICHAISHVILI, Jozef HRITZ and Nunu METREVEL. Quadruplex Priming Amplification at a Range of Human Body Temperature. Biointerface Research in Applied Chemistry. Bucuresti: AMG Transcend Association, 2021, vol. 11, No 1, p. 7932-7942. ISSN 2069-5837. Available from: https://dx.doi.org/10.33263/BRIAC111.79327942.
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Basic information
Original name Quadruplex Priming Amplification at a Range of Human Body Temperature
Authors GVARJALADZE, David, Tamari GULUA, Shota GOGICHAISHVILI, Jozef HRITZ (703 Slovakia, guarantor, belonging to the institution) and Nunu METREVEL.
Edition Biointerface Research in Applied Chemistry, Bucuresti, AMG Transcend Association, 2021, 2069-5837.
Other information
Original language English
Type of outcome Article in a journal
Field of Study 10403 Physical chemistry
Country of publisher Romania
Confidentiality degree is not subject to a state or trade secret
WWW URL
RIV identification code RIV/00216224:14740/21:00120870
Organization unit Central European Institute of Technology
Doi http://dx.doi.org/10.33263/BRIAC111.79327942
UT WoS 000570974900052
Keywords in English quadruplex; DNA amplification; the point of care; lead cations; fluorescence
Tags rivok
Tags International impact, Reviewed
Changed by Changed by: Mgr. Pavla Foltynová, Ph.D., učo 106624. Changed: 30/1/2024 09:46.
Abstract
Quadruplex priming amplification (QPA) is a very simple amplification assay in which the isothermal amplification is performed using an only DNA polymerase, and detection is conducted by the intrinsic fluorescence of the primers. QPA employs specific G-rich sequences as primers that, upon polymerase elongation at specific temperatures, spontaneously dissociate from the primer binding sites (PBS) and fold into a monomolecular quadruplex. Fluorescent nucleotide analogs, such as 3-methyl isoxanthopterin (3MI), when incorporated into these primers, emit light upon a quadruplex formation and permit simple, specific, and sensitive quantification without the attachment of probe molecules. Previously has developed QPA assays with truncated targets and potassium cations that demonstrate an optimal amplification around 55 degrees C. Here, we designed QPA assays with truncated target and led cations at a range of human body temperature. Lead cations reveal the most rapid amplification than potassium and strontium cations. QPA can be applied as a method for the implementation of simple and cheap diagnostics (point of care (POC)), as well as development at a range of 35-45 degrees C temperature, which will make this method more convenient for using it in molecular diagnostics.
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