Design of dual metal ions/dual amino acids integrated photoluminescent logic gate by high-molecular weight protein-localized Au nanoclusters

Proteins are excellent templates and stabilizers for Au nanoclusters (NCs) because of their abundant thiol groups and unique internal environments. However, high-molecular weight (MW) proteins with special quaternary structures are rarely reported as such templates. Considering that proteins may aff...

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Published inNano research Vol. 11; no. 1; pp. 311 - 322
Main Authors Liu, Liu, Jiang, Hui, Wang, Xuemei
Format Journal Article
LanguageEnglish
Published Beijing Tsinghua University Press 2018
Springer Nature B.V
Subjects
Alkaline phosphatase
Amino acids
Atomic/Molecular Structure and Spectra
Biomedicine
Biotechnology
Catalase
Chemistry and Materials Science
Condensed Matter Physics
Copper
Cysteine
Fibrinogen
Histidine
Ions
Logic circuits
Masking
Materials Science
Mercury (metal)
Metal ions
Molecular weight
Nanoclusters
Nanotechnology
Photoluminescence
Photons
Proteins
Research Article
蛋白质;氨基酸;局部性;逻辑门;Au;重量;分子;双金属
metal ions
proteins
gold nanoclusters
amino acids
logic gate
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Summary:Proteins are excellent templates and stabilizers for Au nanoclusters (NCs) because of their abundant thiol groups and unique internal environments. However, high-molecular weight (MW) proteins with special quaternary structures are rarely reported as such templates. Considering that proteins may afford different spatial configurations as templates for Au NCs, we focused on alkaline phosphatase, catalase, and fibrinogen (MW range from 150 to 340 kDa) as direct templates for synthesizing Au NCs. We demonstrated that both Cu2~ and Hg2~ could induce photoluminescence (PL) quenching of these Au NCs, while their binding mech- anisms were different. Therefore, significant PL recovery by amino acids, e.g., histidine and cysteine, was observed for Cu2+-treated Au NCs, but not Hg2+-treated Au NCs, allowing for selective detection of Hg2+ by using histidine as a masking agent. The detection ranges were 0.06-2.0 DM for Hg2+ and 0.04-5.0 DM for Cu2+, with low limits of detection of 0.02 and 0.01μM, respectively. The PL change showed opposite tendency for histidine and cysteine at higher concentrations, resulting in different PL outputs. Using dual metal ion and dual amino acid combinations, an integrated PL logic gate was fabricated. This work improves the understanding of the PL mechanisms of complicated protein-localized Au NCs.
Bibliography:gold nanoclusters,proteins,logic gate,metal ions,amino acids
11-5974/O4
Proteins are excellent templates and stabilizers for Au nanoclusters (NCs) because of their abundant thiol groups and unique internal environments. However, high-molecular weight (MW) proteins with special quaternary structures are rarely reported as such templates. Considering that proteins may afford different spatial configurations as templates for Au NCs, we focused on alkaline phosphatase, catalase, and fibrinogen (MW range from 150 to 340 kDa) as direct templates for synthesizing Au NCs. We demonstrated that both Cu2~ and Hg2~ could induce photoluminescence (PL) quenching of these Au NCs, while their binding mech- anisms were different. Therefore, significant PL recovery by amino acids, e.g., histidine and cysteine, was observed for Cu2+-treated Au NCs, but not Hg2+-treated Au NCs, allowing for selective detection of Hg2+ by using histidine as a masking agent. The detection ranges were 0.06-2.0 DM for Hg2+ and 0.04-5.0 DM for Cu2+, with low limits of detection of 0.02 and 0.01μM, respectively. The PL change showed opposite tendency for histidine and cysteine at higher concentrations, resulting in different PL outputs. Using dual metal ion and dual amino acid combinations, an integrated PL logic gate was fabricated. This work improves the understanding of the PL mechanisms of complicated protein-localized Au NCs.
ISSN:1998-0124
1998-0000
DOI:10.1007/s12274-017-1633-0