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Functional and genetic dissection of mechanosensory organs of \(Drosophila\) \(melanogaster\)
(2016)
In Drosophila larvae and adults, chordotonal organs (chos) are highly versatile mechanosensors
that are essential for proprioception, touch sensation and hearing. Chos share molecular,
anatomical and functional properties with the inner ear hair cells of mammals. These multiple
similarities make chos powerful models for the molecular study of mechanosensation.
In the present study, I have developed a preparation to directly record from the sensory neurons
of larval chos (from the lateral chos or lch5) and managed to correlate defined mechanical inputs
with the corresponding electrical outputs. The findings of this setup are described in several case
studies.
(1) The basal functional lch5 parameters, including the time course of response during continuous
mechanical stimulation and the recovery time between successive bouts of stimulation, was
characterized.
(2) The calcium-independent receptor of α-latrotoxin (dCIRL/Latrophilin), an Adhesion class G
protein-coupled receptor (aGPCR), is identified as a modulator of the mechanical signals
perceived by lch5 neurons. The results indicate that dCIRL/Latrophilin is required for the
perception of external and internal mechanical stimuli and shapes the sensitivity of neuronal
mechanosensation.
(3) By combining this setup with optogenetics, I have confirmed that dCIRL modulates lch5
neuronal activity at the level of their receptor current (sensory encoding) rather than their ability
to generate action potentials.
(4) dCIRL´s structural properties (e.g. ectodomain length) are essential for the mechanosensitive
properties of chordotonal neurons.
(5) The versatility of chos also provides an opportunity to study multimodalities at multiple levels.
In this context, I performed an experiment to directly record neuronal activities at different
temperatures. The results show that both spontaneous and mechanically evoked activity increase
in proportion to temperature, suggesting that dCIRL is not required for thermosensation in chos.
These findings, from the development of an assay of sound/vibration sensation, to neuronal
signal processing, to molecular aspects of mechanosensory transduction, have provided the first
insights into the mechanosensitivity of dCIRL.
In addition to the functional screening of peripheral sensory neurons, another
electrophysiological approach was applied in the central nervous system: dCIRL may impact the
excitability of the motor neurons in the ventral nerve cord (VNC). In the second part of my work,
whole-cell patch clamp recordings of motor neuron somata demonstrated that action potential
firing in the dCirl\(^K\)\(^O\) did not differ from control samples, indicating comparable membrane
excitability.
G protein-coupled receptors of the Adhesion family (aGPCRs) comprise the second largest group within the GPCR realm with over 30 mammalian homologs. They contain a unique structure with unusually large extracellular domains (ECDs) holding many structural folds known to mediate cell-cell and cell-matrix interactions. Furthermore, aGPCRs undergo autoproteolytic cleavage at the GPCR proteolysis site (GPS), an integral portion of the GPCR autoproteolysis inducing (GAIN) domain. Thus far, it is largely unknown if and how self-cleavage affects aGPCR activation and signaling and how these signals may shape the physiological function of cells.
Latrophilin, alternatively termed the calcium-independent receptor of α-latrotoxin (CIRL) constitutes a highly conserved, prototypic aGPCR and has been assigned roles in various biological processes such as synaptic development and maturation or the regulation of neurotransmitter release. The Drosophila melanogaster homolog dCIRL is found in numerous sensory neurons including the mechanosensory larval pentascolopidial chordotonal organs (CHOs), which rely on dCIRL function in order to sense mechanical cues and to modulate the mechanogating properties of present ionotropic receptors.
This study reveals further insight into the broad distribution of dCirl expression throughout the larval central nervous system, at the neuromuscular junction (NMJ), as well as subcellular localization of dCIRL in distal dendrites and cilia of chordotonal neurons. Furthermore, targeted mutagenesis which disabled GPS cleavage of dCIRL left intracellular trafficking in larval CHOs unaffected and proved autoproteolysis is not required for dCIRL function in vivo. However, substitution of a threonine residue, intrinsic to a putative tethered agonist called Stachel that has previously been documented for several other aGPCRs, abrogated receptor function. Conclusively, while this uncovered the presence of Stachel in dCIRL, it leaves the question about the biological relevance of the predetermined breaking point at the GPS unanswered. In an independent approach, the structure of the “Inter-RBL-HRM” (IRH) region, the region linking the N-terminal Rhamnose-binding lectin-like (RBL) and the hormone receptor motif (HRM) domains of dCIRL, was analyzed. Results suggest random protein folding, excessive glycosylation, and a drastic expansion of the size of IRH. Therefore, the IRH might represent a molecular spacer ensuring a certain ECD dimension, which in turn may be a prerequisite for proper receptor function.
Taken together, the results of this study are consistent with dCIRL’s mechanoceptive faculty and its role as a molecular sensor that translates mechanical cues into metabotropic signals through a yet undefined Stachel-dependent mechanism.