Allosteric Switching of Calmodulin in a <i>Mycobacterium smegmatis</i> porin A (MspA) Nanopore‐Trap

Liu, Yao; Pan, Tiezheng; Wang, Kefan; Wang, Yuqin; Yan, Shuanghong; Wang, Liying; Zhang, Shanyu; Du, Xiaoyu; Jia, Wendong; Zhang, Panke; Chen, Hong‐Yuan; Huang, Shuo

doi:10.1002/ange.202110545

“…[ 18‐19 ] This work provides a new path to de novo design of protein channels with customized transmembrane traffic functions. Besides, relying on the ionic transport, nanopore electro measurement not only exhibits excellent performance for protein profiling, [ 20‐22 ] but also offers opportunities to illustrate phenomena of protein conformational changes, [ 23 ] protein‐protein interaction, [ 24‐25 ] and explore enzyme dynamics in real‐time manner. [ 26‐27 ] Interestingly, nanopore is also possible at this stage, to directly identify the detailed sequence changes taking place during a biosynthesis of a protein, by enzymatic modifications (post‐translational modifications), [ 28‐29 ] and decoding (sequencing).…”

Section: Background and Originality Contentmentioning

confidence: 99%

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore^†

Song

¹

,

Wang

²

,

Zhang

³

et al. 2023

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Comprehensive Summary Carbonic anhydrase accounts for catalytic reaction of CO2/HCO3– transformation, thus resulting in neutralization and acidification of the cellular environment, thereby favoring tumor development. Hence, it is a classical protein model of greatly biocatalytic significance as well as a highly expressed biomarker with renal tumor. We herein proposed a single‐molecule measurement on carbonic anhydrase using MspA nanopore, in [BMIM+] and asymmetric K+/Ca2+ cationic coordinated environment, instead of usual symmetric KCl/NaCl electrolyte. Significantly, our empirical analysis showed that asymmetric K+/Ca2+ cationic environment contributes to distinguishable current modulations, thus yielding better resolution for carbonic anhydrase measurement, which is independent of applied voltage and more importantly, is stable enough at varied pH conditions and for very low concentration test in urine sample. Our results provide a classical model for nanopore protein analysis, and may also permit biocatalytic measurement at single‐molecule level.

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A Nanopore‐Based Saccharide Sensor

Zhang

¹

,

Cao

²

,

Fan

³

et al. 2022

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Saccharides play critical roles in many forms of cellular activities. Saccharide structures are however complicated and similar, setting a technical hurdle for direct identification. Nanopores, which are emerging single molecule tools sensitive to minor structural differences between analytes, can be engineered to identity saccharides. A hetero‐octameric Mycobacterium smegmatis porin A nanopore containing a phenylboronic acid was prepared, and was able to clearly identify nine monosaccharide types, including D‐fructose, D‐galactose, D‐mannose, D‐glucose, L‐sorbose, D‐ribose, D‐xylose, L‐rhamnose and N‐acetyl‐D‐galactosamine. Minor structural differences between saccharide epimers can also be distinguished. To assist automatic event classification, a machine learning algorithm was developed, with which a general accuracy score of 0.96 was achieved. This sensing strategy is generally suitable for other saccharide types and may bring new insights to nanopore saccharide sequencing.

show abstract

A Nanopore‐Based Saccharide Sensor

Zhang

¹

,

Cao

²

,

Fan

³

et al. 2022

Self Cite

View full text Add to dashboard Cite

Saccharides play critical roles in many forms of cellular activities. Saccharide structures are however complicated and similar, setting a technical hurdle for direct identification. Nanopores, which are emerging single molecule tools sensitive to minor structural differences between analytes, can be engineered to identity saccharides. A hetero‐octameric Mycobacterium smegmatis porin A nanopore containing a phenylboronic acid was prepared, and was able to clearly identify nine monosaccharide types, including D‐fructose, D‐galactose, D‐mannose, D‐glucose, L‐sorbose, D‐ribose, D‐xylose, L‐rhamnose and N‐acetyl‐D‐galactosamine. Minor structural differences between saccharide epimers can also be distinguished. To assist automatic event classification, a machine learning algorithm was developed, with which a general accuracy score of 0.96 was achieved. This sensing strategy is generally suitable for other saccharide types and may bring new insights to nanopore saccharide sequencing.

show abstract

Allosteric Switching of Calmodulin in a Mycobacterium smegmatis porin A (MspA) Nanopore‐Trap

Cited by 5 publications

References 73 publications

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore^†

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore^†

A Nanopore‐Based Saccharide Sensor

A Nanopore‐Based Saccharide Sensor

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Allosteric Switching of Calmodulin in a Mycobacterium smegmatis porin A (MspA) Nanopore‐Trap

Cited by 5 publications

References 73 publications

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore†

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore†

A Nanopore‐Based Saccharide Sensor

A Nanopore‐Based Saccharide Sensor

Contact Info

Product

Resources

About

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore^†

Single‐Molecule Measurement of Carbonic Anhydrase in Cation Coordinated Environment Using MspA Nanopore^†