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RNA Mango-based sensors for lead.

Annyesha Biswas1, Saurja DasGupta1,2,3

  • 1Department of Chemistry and Biochemistry, University of Notre Dame, Notre Dame, IN 46556, USA. sdasgupta@nd.edu.

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A novel RNA Mango aptamer sensor effectively detects lead (Pb2+) at low nanomolar levels. This cost-effective, fluorescence-based tool offers sensitive and selective lead monitoring in water samples.

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Area of Science:

  • Biochemistry
  • Molecular Biology
  • Environmental Science

Background:

  • Lead (Pb2+) toxicity is a significant global health concern, necessitating rapid and accessible detection methods.
  • Existing lead detection tools often lack the desired sensitivity, cost-effectiveness, or ease of use.
  • RNA aptamers offer potential as molecular recognition elements for biosensor development.

Purpose of the Study:

  • To develop and validate a sensitive and selective fluorescence-based sensor for lead (Pb2+) detection using the RNA Mango aptamer.
  • To investigate the mechanism of Pb2+-induced fluorescence activation in the RNA Mango system.
  • To assess the sensor's performance, including its limit of detection and selectivity, for practical applications.

Main Methods:

  • Utilizing the RNA Mango aptamer as a recognition element for Pb2+.
  • Investigating Pb2+-induced G-quadruplex formation and subsequent dye binding (TO1-biotin, TO3-biotin, thioflavin-T).
  • Characterizing fluorescence properties and determining binding affinities (KD) and limits of detection (LOD).

Main Results:

  • RNA Mango, in conjunction with TO1-biotin, demonstrated high binding affinity for Pb2+ (KD ~ 40 nM).
  • The sensor achieved sub-micromolar affinity for Pb2+ with all tested dyes.
  • Detected low nanomolar concentrations of Pb2+ (LOD 2-16 nM), below permissible drinking water limits.
  • Exhibited remarkable selectivity for Pb2+ and successfully detected it in tap water samples.

Conclusions:

  • The RNA Mango aptamer serves as a sensitive and selective platform for developing simple, inexpensive fluorescence-based lead sensors.
  • This RNA-based sensor offers a promising alternative for rapid and cost-effective monitoring of lead contamination.
  • The findings expand the utility of RNA aptamers in environmental monitoring and diagnostics.