Innexin expression and localization in the Drosophila antenna indicate gap junction or hemichannel involvement in antennal chemosensory sensilla.

Odor detection in insects is largely mediated by structures on antennae called sensilla, which feature a strongly conserved architecture and repertoire of olfactory sensory neurons (OSNs) and various support cell types. In Drosophila, OSNs are tightly apposed to supporting cells, whose connection with neurons and functional roles in odor detection remain unclear. Coupling mechanisms between these neuronal and non-neuronal cell types have been suggested based on morphological observations, concomitant physiological activity during odor stimulation, and known interactions that occur in other chemosensory systems. For instance, it is not known whether cell-cell coupling via gap junctions between OSNs and neighboring cells exists, or whether hemichannels interconnect cellular and extracellular sensillum compartments. Here, we show that innexins, which form hemichannels and gap junctions in invertebrates, are abundantly expressed in adult drosophilid antennae. By surveying antennal transcriptomes and performing various immunohistochemical stainings in antennal tissues, we discover innexin-specific patterns of expression and localization, with a majority of innexins strongly localizing to glial and non-neuronal cells, likely support and epithelial cells. Finally, by injecting gap junction-permeable dye into a pre-identified sensillum, we observe no dye coupling between neuronal and non-neuronal cells. Together with evidence of non-neuronal innexin localization, we conclude that innexins likely do not conjoin neurons to support cells, but that junctions and hemichannels may instead couple support cells among each other or to their shared sensillum lymph to achieve synchronous activity. We discuss how coupling of sensillum microenvironments or compartments may potentially contribute to facilitate chemosensory functions of odor sensing and sensillum homeostasis.

Independent Innexin Radiation Shaped Signaling in Ctenophores.

Innexins facilitate cell-cell communication by forming gap junctions or nonjunctional hemichannels, which play important roles in metabolic, chemical, ionic, and electrical coupling. The lack of knowledge regarding the evolution and role of these channels in ctenophores (comb jellies), the likely sister group to the rest of animals, represents a substantial gap in our understanding of the evolution of intercellular communication in animals. Here, we identify and phylogenetically characterize the complete set of innexins of four ctenophores: Mnemiopsis leidyi, Hormiphora californensis, Pleurobrachia bachei, and Beroe ovata. Our phylogenetic analyses suggest that ctenophore innexins diversified independently from those of other animals and were established early in the emergence of ctenophores. We identified a four-innexin genomic cluster, which was present in the last common ancestor of these four species and has been largely maintained in these lineages. Evidence from correlated spatial and temporal gene expression of the M. leidyi innexin cluster suggests that this cluster has been maintained due to constraints related to gene regulation. We describe the basic electrophysiological properties of putative ctenophore hemichannels from muscle cells using intracellular recording techniques, showing substantial overlap with the properties of bilaterian innexin channels. Together, our results suggest that the last common ancestor of animals had gap junctional channels also capable of forming functional innexin hemichannels, and that innexin genes have independently evolved in major lineages throughout Metazoa.

Gap junction proteins and the wiring (Rewiring) of neuronal circuits.

The unique morphology and pattern of synaptic connections made by a neuron during development arise in part by an extended period of growth in which cell-cell interactions help to sculpt the arbor into its final shape, size, and participation in different synaptic networks. Recent experiments highlight a guiding role played by gap junction proteins in controlling this process. Ectopic and overexpression studies in invertebrates have revealed that the selective expression of distinct gap junction genes in neurons and glial cells is sufficient to establish selective new connections in the central nervous systems of the leech (Firme et al. [2012]: J Neurosci 32:14265-14270), the nematode (Rabinowitch et al. [2014]: Nat Commun 5:4442), and the fruit fly (Pézier et al., 2016: PLoS One 11:e0152211). We present here an overview of this work and suggest that gap junction proteins, in addition to their synaptic/communicative functions, have an instructive role as recognition and adhesion factors. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 77: 575-586, 2017.

Expression of a dominant negative mutant innexin in identified neurons and glial cells reveals selective interactions among gap junctional proteins.

Neurons and glia of the medicinal leech CNS express different subsets of the 21 innexin genes encoded in its genome. We report here that the punctal distributions of fluorescently tagged innexin transgenes varies in a stereotypical pattern depending on the innexin expressed. Furthermore, whereas certain innexins colocalize extensively (INX1 and INX14), others do not (e.g., INX1 and INX2 or INX6). We then demonstrate that the mutation of a highly conserved proline residue in the second transmembrane domain of innexins creates a gap junction protein with dominant negative properties. Coexpressing the mutated INX1 gene with its wild type blocks the formation of fluorescent puncta and decouples the expressing neuron from its normal gap junction-coupled network of cells. Similarly, expression of an INX2 mutant transgene (a glial cell innexin), blocks endogenous INX2 puncta and wild-type transgene puncta, and decouples the glial cell from the other glial cells in the ganglion. We show in cell culture with dye-uptake and plasma membrane labeling experiments that the mutant innexin transgene is not expressed on the cell membrane but instead appears to accumulate in the cell's perinuclear region. Lastly, we use these mutant innexin transgenes to show that the INX1 mutant transgene blocks not only INX1 puncta formation, but also puncta of INX14, with which INX1 usually colocalizes. By contrast, the formation of INX6 puncta was unaffected by the INX1 mutant. Together, these experiments suggest that leech innexins can selectively interact with one another to form gap junction plaques, which are heterogeneously located in cellular arbors. © 2013 Wiley Periodicals, Inc. Develop Neurobiol 73: 571-586, 2013.