Curated Optogenetic Publication Database

Abstract: Investigating astrocyte-neuron dynamics following ischemic stroke is essential for understanding post-stroke recovery mechanisms. However, current methodologies often fail to capture real-time interactions between neurons and astrocytes in animals executing specific behavioral tasks, limiting our ability to investigate the acute phase of stroke pathology. This protocol presents an integrated method that combines photothrombotic stroke modeling with simultaneous multichannel electrophysiology recording and fiber photometry in awake, behaving mice using a custom-fabricated optrode. The protocol includes focal ischemia induction via photothrombosis followed by simultaneous recording of neuronal spikes and astrocytic calcium transients. The optrode enables concurrent delivery of photothrombosis, calcium signal recording, and optogenetic manipulation without requiring separate surgical procedures. Representative results validate the success in simultaneous recording of astrocytic calcium signal and neuronal spiking. Optogenetic manipulation of astrocytes produces measurable changes in neuronal firing patterns (reduction in firing frequency of pyramidal neurons by 1.55 ± 0.45 Hz and interneuron by 3.64 ± 1.37 Hz compared to pre-optogenetic stimulation, n = 2), confirming that the system is capable of investigating astrocyte-neuron interactions. This integrated approach addresses critical gaps in stroke research methodology by providing real-time, multimodal recordings from the acute to chronic stage of stroke in behaving animals.

Abstract: Microbial biosynthesis, as an alternative method for producing quantum dots (QDs), has gained attention because it can be conducted under mild and environmentally friendly conditions, distinguishing it from conventional chemical and physical synthesis approaches. However, there is currently no method to selectively control this biosynthesis process in a subset of microbes within a population using external stimuli. In this study, we have attained precise and selective control over the microbial biosynthesis of QDs through the utilization of an optogenetically engineered Escherichia coli (E. coli). The recombinant E. coli is designed to express smCSE enzyme, under the regulation of eLightOn system, which can be activated by blue light. The smCSE enzymes use L-cysteine and Cd2+ as substrates to form CdS QDs. This system enables light-inducible bacterial biosynthesis of QDs in precise patterns within a hydrogel for information encryption. As the biosynthesis progresses, the optical characteristics of the QDs change, allowing living materials containing the recombinant E. coli to display time-dependent patterns that self-destruct after reading. Compared to static encryption using fluorescent QD inks, dynamic information encryption based on living materials offers enhanced security.