Chemo-optogenetic Protein Translocation System Using a Photoactivatable Self-Localizing Ligand.

Manipulating subcellular protein localization using light is a powerful approach for controlling signaling processes with high spatiotemporal precision. The most widely used strategy for this is based on light-induced protein heterodimerization. The use of small synthetic molecules that can control the localization of target proteins in response to light without the need for a second protein has several advantages. However, such methods have not been well established. Herein, we present a chemo-optogenetic approach for controlling protein localization using a photoactivatable self-localizing ligand (paSL). We developed a paSL that can recruit tag-fused proteins of interest from the cytoplasm to the plasma membrane within seconds upon light illumination. This paSL-induced protein translocation (paSLIPT) is reversible and enables the spatiotemporal control of signaling processes in living cells, even in a local region. paSLIPT can also be used to implement simultaneous optical stimulation and multiplexed imaging of molecular processes in a single cell, offering an attractive and novel chemo-optogenetic platform for interrogating and engineering dynamic cellular functions.

Influence of ionizing radiation on the antimicrobial activity of the antibiotics sulfamethoxazole and trimethoprim.

The response of the antimicrobial compounds sulfamethoxazole (SMX) and trimethoprim (TMP) - individually and in mixtures - to ionizing radiation was investigated using laboratory prepared mixtures and a commercial pharmaceutical formulation. The residual antibacterial activity of the solutions was monitored using Staphylococcus aureus and Escherichia coli test strains. Based on antibacterial activity, SMX was more susceptible to ionizing radiation as compared to TMP. The antibacterial activity of SMX and TMP was completely eliminated at 0.2 kGy and 0.8 kGy, respectively. However, when SMX and TMP were in a mixture, the dose required to eliminate the antibacterial activity was 10 kGy, implying a synergistic antibacterial activity when these are present in mixtures. Only when the antibiotic concentration was below the Minimum Inhibitory Concentration of TMP (i.e., 2 µmol dm-3) did the antibacterial activity of the SMX and TMP mixture disappear. These results imply that the synergistic antimicrobial activity of antimicrobial compounds in pharmaceutical waste streams is a strong possibility. Therefore, antimicrobial activity assays should be included when evaluating the use of ionizing radiation technology for the remediation of pharmaceutical or municipal waste streams.