Multimodal Control of Bacterial Gene Expression by Red and Blue Light

By applying sensory photoreceptors, optogenetics realizes the light-dependent control of cellular events and state. Given reversibility, noninvasiveness, and exquisite spatiotemporal precision, optogenetic approaches enable innovative use cases in cell biology, synthetic biology, and biotechnology. In this chapter, we detail the implementation of the pREDusk, pREDawn, pCrepusculo, and pAurora optogenetic circuits for controlling bacterial gene expression by red and blue light, respectively. The protocols provided here guide the practical use and multiplexing of these circuits, thereby enabling graded protein production in bacteria at analytical and semi-preparative scales.

Pulsatile illumination for photobiology and optogenetics

Living organisms exhibit a wide range of intrinsic adaptive responses to incident light. Likewise, in optogenetics, biological systems are tailored to initiate predetermined cellular processes upon light exposure. As genetically encoded, light-gated actuators, sensory photoreceptors are at the heart of these responses in both the natural and engineered scenarios. Upon light absorption, photoreceptors enter a series of generally rapid photochemical reactions leading to population of the light-adapted signaling state of the receptor. Notably, this state persists for a while before thermally reverting to the original dark-adapted resting state. As a corollary, the inactivation of photosensitive biological circuits upon light withdrawal can exhibit substantial inertia. Intermittent illumination of suitable pulse frequency can hence maintain the photoreceptor in its light-adapted state while greatly reducing overall light dose, thereby mitigating adverse side effects. Moreover, several photoreceptor systems may be actuated sequentially with a single light color if they sufficiently differ in their inactivation kinetics. Here, we detail the construction of programmable illumination devices for the rapid and parallelized testing of biological responses to diverse lighting regimes. As the technology is based on open electronics and readily available, inexpensive components, it can be adopted by most laboratories at moderate expenditure. As we exemplify for two use cases, the programmable devices enable the facile interrogation of diverse illumination paradigms and their application in optogenetics and photobiology.

Primer-Aided Truncation for the Creation of Hybrid Proteins

Proteins frequently display modular architecture with several domains and segments connected by linkers. Proper protein functionality hinges on finely orchestrated interactions among these constituent elements. The underlying modularity lends itself to the engineering of hybrid proteins via modular rewiring; novel properties can thus be obtained, provided the linkers connecting the individual elements are conducive to productive interactions. As a corollary, the process of protein engineering often encompasses the generation and screening of multiple linker variants. To aid these steps, we devised the PATCHY method (primer-aided truncation for the creation of hybrid proteins) to readily generate hybrid gene libraries of predefined composition. We applied PATCHY to the mechanistic characterization of hybrid receptors that possess blue-light-regulated histidine kinase activity. Comprehensive sampling of linker composition revealed that catalytic activity and response to light are primarily functions of linker length. Variants with linkers of 7n residues mostly have light-repressed activity but those with 7n + 1 residues mostly have inverted, light-induced activity. We further probed linker length in the context of single residue exchanges that also lead to an inversion of the signal response. As in the original context, activity is only observed for certain periodic linker lengths. Taken together, these results provide mechanistic insight into signaling strategies employed by sensory photoreceptors and sensor histidine kinases. PATCHY represents an adequate and facile method to efficiently generate and probe hybrid gene libraries and to thereby identify key determinants for proper function.

A Fluorometric Activity Assay for Light-Regulated Cyclic-Nucleotide-Monophosphate Actuators

As a transformative approach in neuroscience and cell biology, optogenetics grants control over manifold cellular events with unprecedented spatiotemporal definition, reversibility, and noninvasiveness. Sensory photoreceptors serve as genetically encoded, light-regulated actuators and hence embody the cornerstone of optogenetics. To expand the scope of optogenetics, ever more naturally occurring photoreceptors are being characterized, and synthetic photoreceptors with customized, light-regulated function are being engineered. Perturbational control over intracellular cyclic-nucleotide-monophosphate (cNMP) levels is achieved via sensory photoreceptors that catalyze the making and breaking of these second messengers in response to light. To facilitate discovery, engineering and quantitative characterization of such light-regulated cNMP actuators, we have developed an efficient fluorometric assay. Both the formation and the hydrolysis of cNMPs are accompanied by proton release which can be quantified with the fluorescent pH indicator 2',7'-bis-(2-carboxyethyl)-5-(and-6)-carboxyfluorescein (BCECF). This assay equally applies to nucleotide cyclases, e.g., blue-light-activated bPAC, and to cNMP phosphodiesterases, e.g., red-light-activated LAPD. Key benefits include potential for parallelization and automation, as well as suitability for both purified enzymes and crude cell lysates. The BCECF assay hence stands to accelerate discovery and characterization of light-regulated actuators of cNMP metabolism.

Guidelines for Photoreceptor Engineering

Sensory photoreceptors underpin optogenetics by mediating the noninvasive and reversible perturbation of living cells by light with unprecedented temporal and spatial resolution. Spurred by seminal optogenetic applications of natural photoreceptors, the engineering of photoreceptors has recently garnered wide interest and has led to the construction of a broad palette of novel light-regulated actuators. Photoreceptors are modularly built of photosensors that receive light signals, and of effectors that carry out specific cellular functions. These modules have to be precisely connected to allow efficient communication, such that light stimuli are relayed from photosensor to effector. The engineering of photoreceptors benefits from a thorough understanding of the underlying signaling mechanisms. This chapter gives a brief overview of key characteristics and signal-transduction mechanisms of sensory photoreceptors. Adaptation of these concepts in photoreceptor engineering has enabled the generation of novel optogenetic tools that greatly transcend the repertoire of natural photoreceptors.