| Oct 10, 2025 |
Breakthrough mirror-image nanopores open door to new biomedical applicationsResearchers built and tested the first mirror-image nanopore made entirely from D-amino acids, the reverse forms of natural proteins.(Nanowerk News) For the first time, researchers have successfully fabricated and characterized a fully functional mirror-image nanopore—a molecular gateway built entirely from D-amino acids, the mirror-image forms of the natural building blocks of proteins. |
| The work, led by Prof. Dr. Kozhinjampara R. Mahendran at the Rajiv Gandhi Centre for Biotechnology (India) in collaboration with Constructor University and other partners, demonstrates not only a major milestone in nanoscience but also opens promising biomedical applications, including potential cancer therapies. |
| Proteins in nature are almost exclusively built from L-amino acids, while their D-amino acid counterparts usually play only minor roles. Constructing entire proteins from D-amino acids is extremely challenging, yet offers striking advantages: such mirror-image structures are often more resistant to degradation and may interact differently with biological systems. |
| In this study (Nature Communications, "Fabrication of cytotoxic mirror image nanopores"), the team designed a synthetic stable and well-defined D-peptide pore called DpPorA. Remarkably, by modifying the charge distribution, they were able to create superior versions of these pores with enhanced conductance and selectivity under different salt conditions. |
| Experiments revealed that these pores can detect a broad spectrum of biomolecules at the single-molecule level, including peptides, cyclic sugars, certain proteins including one which central to Parkinson’s disease research. Fluorescence imaging confirmed that the pores form large, flexible channels in membranes, enabling size-dependent transport of molecules. |
| The simulations carried out by scientists at Constructor University were key to verifying the architecture of the mirror-image pore. By comparing the D-pore with its natural L-counterpart, the molecular dynamics studies confirmed that the two are perfect structural reflections, while also explaining subtle differences in conductance and selectivity observed in the experiments. |
| “The computational work gave us the confidence that we were indeed looking at a true mirror-image pore,” explains Dr. Kalyanashis Jana, postdoctoral researcher in Kleinekathöfer’s group and equally contributing first author of the paper. |
| Beyond fundamental science, the results suggest exciting biomedical potential. In cell studies, fluorescently tagged mirror-image pores showed strong membrane-disrupting effects in cancer cells but had no impact on normal cells, hinting at selective cytotoxicity that could one day be harnessed for cancer therapy. |
| Source: Constructor University (Note: Content may be edited for style and length) |
