Eduardo R. Macagno scite author profile

Several kinds of sensory organs (SOs) appear in stereotyped positions on the adult Drosophila cuticle. The generation of these SOs requires the activity of the achaete (ac) and scute (sc) genes. To investigate whether ac and sc also provide spatial information for the positioning of SOs, we have analyzed the patterns of expression of these genes in the wing imaginal disc around the time that SO precursors are being specified. We find that expression coincides with and is restricted to areas of the disc where these precursors are known to be located. In the loss-of-function sc 6 mutant, sc RNA is depleted in a single area located in the region where the precursor for the supressed macrochaeta should be found. Moreover, some, and probably all, SOs require expression of these genes to reach the earliest detectable differentiated state. These and other results presented here, together with the finding that expansion of the areas of ac and/or sc expression causes the development of ectopic SOs, indicate that ac and sc promote the determination of SO precursors and delimit the regions of the imaginal discs where they can develop.

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Innexins form two types of channels

Samuels

Locovei

et al. 2007

FEBS Letters

115

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Injury to the central nervous system triggers glial calcium waves in both vertebrates and invertebrates. In vertebrates the pannexin1 ATP-release channel appears to provide for calcium wave initiation and propagation. The innexins, which form invertebrate gap junctions and have sequence similarity with the pannexins, are candidates to form non-junctional membrane channels. Two leech innexins previously demonstrated in glia were expressed in frog oocytes. In addition to making gap junctions, innexins also formed non-junctional membrane channels with properties similar to those of pannexons. In addition, carbenoxolone reversibly blocked the loss of carboxyfluorescein dye into the bath from the giant glial cells in the connectives of the leech nerve cord, which are known to express the innexins we assayed.

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Microbial Challenge Promotes the Regenerative Process of the Injured Central Nervous System of the Medicinal Leech by Inducing the Synthesis of Antimicrobial Peptides in Neurons and Microglia

et al. 2008

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Following trauma, the CNS of the medicinal leech, unlike the mammalian CNS, has a strong capacity to regenerate neurites and synaptic connections that restore normal function. In this study, we show that this regenerative process is enhanced by a controlled bacterial infection, suggesting that induction of regeneration of normal CNS function may depend critically upon the coinitiation of an immune response. We explore the interaction between the activation of a neuroimmune response and the process of regeneration by assaying the potential roles of two newly characterized antimicrobial peptides. Our data provide evidence that microbial components differentially induce the transcription, by microglial cells, of both antimicrobial peptide genes, the products of which accumulate rapidly at sites in the CNS undergoing regeneration following axotomy. Using a preparation of leech CNS depleted of microglial cells, we also demonstrate the production of antimicrobial peptides by neurons. Interestingly, in addition to exerting antibacterial properties, both peptides act as promoters of the regenerative process of axotomized leech CNS. These data are the first to report the neuronal synthesis of antimicrobial peptides and their participation in the immune response and the regeneration of the CNS. Thus, the leech CNS appears as an excellent model for studying the implication of immune molecules in neural repair.

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Coding of olfactory information: Topography of odorant receptor expression in the catfish olfactory epithelium

Ngai

Chess

Dowling

et al. 1993

Cell

321

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Discrimination among the vast array of odors requires that the brain discern which of the numerous odorant receptors have been activated. If individual olfactory neurons express only a subset of the odorant receptor repertoire, then the nature of a given odorant can be discerned by identifying which cells have been activated. We performed in situ hybridization experiments demonstrating that individual olfactory neurons express different complements of odorant receptors and are therefore functionally distinct. Thus, a topographic map, defining either the positions of specific neurons in the epithelium or the positions of their projections, may be employed to determine the quality of an olfactory stimulus. Neurons expressing specific receptors appear to be randomly distributed within the olfactory epithelium. These data are consistent with a model in which randomly dispersed olfactory neurons with common receptor specificities project to common glomeruli in the olfactory bulb.

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The medicinal leech genome encodes 21 innexin genes: different combinations are expressed by identified central neurons

Kandarian

Sethi

et al. 2012

Dev Genes Evol

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Gap junctional proteins are important components of signaling pathways required for the development and ongoing functions of all animal tissues, particularly the nervous system, where they function in the intracellular and extracellular exchange of small signaling factors and ions. In animals whose genomes have been sufficiently sequenced, large families of these proteins, connexins, pannexins, and innexins, have been found, with 25 innexins in the nematode Caenorhabditis elegans Starich et al. (Cell Commun Adhes 8: 311-314, 2001) and at least 37 connexins in the zebrafish Danio rerio Cruciani and Mikalsen (Biol Chem 388:253-264, 2009). Having recently sequenced the medicinal leech Hirudo verbana genome, we now report the presence of 21 innexin genes in this species, nine more than we had previously reported from the analysis of an EST-derived transcriptomic database Dykes and Macagno (Dev Genes Evol 216: 185-97, 2006); Macagno et al. (BMC Genomics 25:407, 2010). Gene structure analyses show that, depending on the leech innexin gene, they can contain from 0 to 6 introns, with closely related paralogs showing the same number of introns. Phylogenetic trees comparing Hirudo to another distantly related leech species, Helobdella robusta, shows a high degree of orthology, whereas comparison to other annelids shows a relatively low level. Comparisons with other Lophotrochozoans, Ecdyzozoans and with vertebrate pannexins suggest a low number (one to two) of ancestral innexin/pannexins at the protostome/deuterostome split. Whole-mount in situ hybridization for individual genes in early embryos shows that ∼50% of the expressed innexins are detectable in multiple tissues. Expression analyses using quantitative PCR show that ∼70% of the Hirudo innexins are expressed in the nervous system, with most of these detected in early development. Finally, quantitative PCR analysis of several identified adult neurons detects the presence of different combinations of innexin genes, a property that may underlie the participation of these neurons in different adult coupling circuits.

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