610 Medizin und Gesundheit
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Voltage-gated sodium (Na\(^+\)) channels respond to short membrane depolarization with conformational changes leading to pore opening, Na\(^+\) influx, and action potential (AP) upstroke. In the present study, we coupled channelrhodopsin-2 (ChR2), the key ion channel in optogenetics, directly to the cardiac voltage-gated Na\(^+\) channel (Na\(_v\)1.5). Fusion constructs were expressed in Xenopus laevis oocytes, and electrophysiological recordings were performed by the two-microelectrode technique. Heteromeric channels retained both typical Na\(_v\)1.5 kinetics and light-sensitive ChR2 properties. Switching to the current-clamp mode and applying short blue-light pulses resulted either in subthreshold depolarization or in a rapid change of membrane polarity typically seen in APs of excitable cells. To study the effect of individual K\(^+\) channels on the AP shape, we co-expressed either K\(_v\)1.2 or hERG with one of the Na\(_v\)1.5-ChR2 fusions. As expected, both delayed rectifier K\(^+\) channels shortened AP duration significantly. K\(_v\)1.2 currents remarkably accelerated initial repolarization, whereas hERG channel activity efficiently restored the resting membrane potential. Finally, we investigated the effect of the LQT3 deletion mutant ΔKPQ on the AP shape and noticed an extremely prolonged AP duration that was directly correlated to the size of the non-inactivating Na\(^+\) current fraction. In conclusion, coupling of ChR2 to a voltage-gated Na\(^+\) channel generates optical switches that are useful for studying the effect of individual ion channels on the AP shape. Moreover, our novel optogenetic approach provides the potential for an application in pharmacology and optogenetic tissue-engineering.
Platelets play an essential role in haemostasis. Through granule secretion of second wave mediators and aggregation, they secure vascular integrity. Due to incorrect activation, platelet aggregation and subsequent thrombus formation can cause blood vessel occlusion, leading to ischemia. Patients with defects in platelet production have a low platelet count (thrombocytopenia), which can cause an increased bleeding risk. In vitro platelet generation is still in its development phase. So far, no convincing results have been obtained. For this reason, the health care system still depends on blood donors. Platelets are produced by bone marrow megakaryocytes (MKs), which extend long cytoplasmic protrusions, designated proplatelets, into sinusoidal blood vessels. Due to shear forces, platelets are then released into the bloodstream. The molecular mechanisms underlying platelet production are still not fully understood. However, a more detailed insight of this biological process is necessary to improve the in vitro generation of platelets and to optimise treatment regimens of patients.
Optogenetics is defined as “light-modulation of cellular activity or of animal behaviour by gene transfer of photo-sensitive proteins”. Optogenetics has had a big impact on neuroscience over the last decade. The use of channelrhodopsin 2 (ChR2), a light-sensitive cation channel, made it possible to stimulate neurons precisely and minimally invasive for the first time. Recent developments in the field of optogenetics intend to address a broader scope of cellular and molecular biology.
The aim of this thesis is to establish optogenetics in the field of MK research in order to precisely control and manipulate MK differentiation. An existing “optogenetic toolbox“ was used, which made it possible to light-modulate the cellular concentration of specific signalling molecules and ion conductance in MKs. Expression of the bacterial photoactivated adenylyl cyclase (bPAC) resulted in a significant increase in cAMP concentration after 5 minutes of illumination. Similarly, intracellular cGMP concentrations in MKs expressing photoactivated guanylyl cyclase (BeCyclop) were elevated. Furthermore, proplatelet formation of MKs expressing the light-sensitive ion channels ChR2 and anion channelrhodopsin (ACR) was altered in a light-dependent manner. These results show that MK physiology can be modified by optogenetic approaches. This might help shed new light on the underlying mechanisms of thrombopoiesis.
Aureobasidium pullulans is a black fungus that can adapt to various stressful conditions like hypersaline, acidic, and alkaline environments. The genome of A. pullulans exhibits three genes coding for putative opsins ApOps1, ApOps2, and ApOps3. We heterologously expressed these genes in mammalian cells and Xenopus oocytes. Localization in the plasma membrane was greatly improved by introducing additional membrane trafficking signals at the N-terminus and the C-terminus. In patch-clamp and two-electrode-voltage clamp experiments, all three proteins showed proton pump activity with maximal activity in green light. Among them, ApOps2 exhibited the most pronounced proton pump activity with current amplitudes occasionally extending 10 pA/pF at 0 mV. Proton pump activity was further supported in the presence of extracellular weak organic acids. Furthermore, we used site-directed mutagenesis to reshape protein functions and thereby implemented light-gated proton channels. We discuss the difference to other well-known proton pumps and the potential of these rhodopsins for optogenetic applications.
Optogenetics was developed in the field of neuroscience and is most commonly using light-sensitive rhodopsins to control the neural activities. Lately, we have expanded this technique into plant science by co-expression of a chloroplast-targeted β-carotene dioxygenase and an improved anion channelrhodopsin GtACR1 from the green alga Guillardia theta. The growth of Nicotiana tabacum pollen tube can then be manipulated by localized green light illumination. To extend the application of analogous optogenetic tools in the pollen tube system, we engineered another two ACRs, GtACR2, and ZipACR, which have different action spectra, light sensitivity and kinetic features, and characterized them in Xenopus laevis oocytes, Nicotiana benthamiana leaves and N. tabacum pollen tubes. We found that the similar molecular engineering method used to improve GtACR1 also enhanced GtACR2 and ZipACR performance in Xenopus laevis oocytes. The ZipACR1 performed in N. benthamiana mesophyll cells and N. tabacum pollen tubes with faster kinetics and reduced light sensitivity, allowing for optogenetic control of anion fluxes with better temporal resolution. The reduced light sensitivity would potentially facilitate future application in plants, grown under low ambient white light, combined with an optogenetic manipulation triggered by stronger green light.
The second messengers, cyclic adenosine 3′-5′-monophosphate (cAMP) and cyclic guanosine 3′-5′-monophosphate (cGMP), play important roles in many animal cells by regulating intracellular signaling pathways and modulating cell physiology. Environmental cues like temperature, light, and chemical compounds can stimulate cell surface receptors and trigger the generation of second messengers and the following regulations. The spread of cAMP and cGMP is further shaped by cyclic nucleotide phosphodiesterases (PDEs) for orchestration of intracellular microdomain signaling. However, localized intracellular cAMP and cGMP signaling requires further investigation. Optogenetic manipulation of cAMP and cGMP offers new opportunities for spatio-temporally precise study of their signaling mechanism. Light-gated nucleotide cyclases are well developed and applied for cAMP/cGMP manipulation. Recently discovered rhodopsin phosphodiesterase genes from protists established a new and direct biological connection between light and PDEs. Light-regulated PDEs are under development, and of demand to complete the toolkit for cAMP/cGMP manipulation. In this review, we summarize the state of the art, pros and cons of artificial and natural light-regulated PDEs, and discuss potential new strategies of developing light-gated PDEs for optogenetic manipulation.