Keiko Kikuno scite author profile

Although the corazonin gene (Crz) has been molecularly characterized, little is known concerning the function of this neuropeptide in Drosophila melanogaster. To gain insight into Crz function in Drosophila, we have investigated the developmental regulation of Crz expression and the morphology of corazonergic neurons. From late embryo to larva, Crz expression is consistently detected in three neuronal groups: dorso-lateral Crz neurons (DL), dorso-medial Crz neurons (DM), and Crz neurons in the ventral nerve cord (vCrz). Both the vCrz and DM groups die via programmed cell death during metamorphosis, whereas the DL neurons persist to adulthood. In adults, Crz is expressed in a cluster of six to eight neurons per lobe in the pars lateralis (DLP), in numerous neuronal cells in the optic lobes, and in a novel group of four abdominal ganglionic neurons present only in males (ms-aCrz). The DLP group consists of two subsets of cells having different developmental origins: embryo and pupa. In the optic lobes, we have detected both Crz transcripts and Crz promoter activity, but no Crz-immunoreactive products, suggesting a post-transcriptional regulation of Crz mRNA. Projections of the ms-aCrz neurons terminate within the ventral nerve cord, implying a role as interneurons. Terminals of the DLP neurons are found in the retrocerebral complex that produces juvenile hormone and adipokinetic hormone. Significant reduction of trehalose levels in adults lacking DLP neurons suggests that DLP neurons are involved in the regulation of trehalose metabolism. Thus, the tissue-, stage-, and sex-specific expression of Crz and the association of Crz with the function of the retrocerebral complex suggest diverse roles for this neuropeptide in Drosophila.

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Drosophila caspases involved in developmentally regulated programmed cell death of peptidergic neurons during early metamorphosis

Lee

Wang

Sehgal

et al. 2010

J of Comparative Neurology

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A great number of obsolete larval neurons in the Drosophila central nervous system are eliminated by developmentally programmed cell death (PCD) during early metamorphosis. To elucidate the mechanisms of neuronal PCD occurring during this period, we undertook genetic dissection of seven currently known Drosophila caspases in the PCD of a group of interneurons (vCrz) that produce corazonin (Crz) neuropeptide in the ventral nerve cord. The molecular death program in the vCrz neurons initiates within 1 hour after pupariation, as demonstrated by the cytological signs of cell death and caspase activation. PCD was significantly suppressed in dronc-null mutants, but not in null mutants of either dredd or strica. A double mutation lacking both dronc and strica impaired PCD phenotype more severely than did a dronc mutation alone, but comparably to a triple dredd/strica/dronc mutation, indicating that dronc is a main initiator caspase, while strica plays a minor role that overlaps with dronc's. As for effector caspases, vCrz PCD requires both ice and dcp-1 functions, as they work cooperatively for a timely removal of the vCrz neurons. Interestingly, the activation of the Ice and Dcp-1 is not solely dependent on Dronc and Strica, implying an alternative pathway to activate the effectors. Two remaining effector caspase genes, decay and damm, found no apparent functions in the neuronal PCD, at least during early metamorphosis. Overall, our work revealed that vCrz PCD utilizes dronc, strica, dcp-1, and ice wherein the activation of Ice and Dcp-1 requires a novel pathway in addition to the initiator caspases.

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Mechanisms of Postecdysis‐Associated Programmed Cell Death of Peptidergic Neurons in Drosophila melanogaster

Lee

Kikuno

Nair

et al. 2013

J of Comparative Neurology

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Crustacean cardioactive peptide (CCAP)-expressing neurons undergo programmed cell death (PCD) within 24 hours after adult eclosion. A subset of the doomed CCAP neurons in the ventral nerve cord also expressed the neuropeptide bursicon and thus are referred to as bursCCAP neurons. In this study, we undertook comprehensive genetic and transgenic analyses to dissect the PCD mechanisms of bursCCAP neurons. Expression of a versatile caspase inhibitor, p35, blocked PCD of bursCCAP neurons, suggesting caspase-dependent apoptosis. Further genetic analyses showed that Dronc/Dark and Drice are key caspases, but they are not sufficient to carry out the PCD fully. We did not find a role for other known caspases, Strica, Dredd, Damm, or Decay. Of interest, Dcp-1 is required not for the death of bursCCAP neurons per se but for the removal of neural projections. DIAP1 is an important survival factor that inhibits premature death of bursCCAP neurons. We found that grim functions as a principal death inducer, whereas other death genes, hid, reaper, and sickle, show no endogenous function. Taken together with other studies, our work supports the role of grim as a major death inducer particularly for the removal of obsolete larval neurons during CNS metamorphosis. Results from the ectopic expression of the mutant grim lacking either N-terminal IBM or internal GH3 domain indicated that both domains are necessary to induce CCAP cell death.

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Essential role of grim-led programmed cell death for the establishment of corazonin-producing peptidergic nervous system during embryogenesis and metamorphosis in Drosophila melanogaster

Lee

Sehgal

Wang

et al. 2013

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SummaryIn Drosophila melanogaster, combinatorial activities of four death genes, head involution defective (hid), reaper (rpr), grim, and sickle (skl), have been known to play crucial roles in the developmentally regulated programmed cell death (PCD) of various tissues. However, different expression patterns of the death genes also suggest distinct functions played by each. During early metamorphosis, a great number of larval neurons unfit for adult life style are removed by PCD. Among them are eight pairs of corazonin-expressing larval peptidergic neurons in the ventral nerve cord (vCrz). To reveal death genes responsible for the PCD of vCrz neurons, we examined extant and recently available mutations as well as RNA interference that disrupt functions of single or multiple death genes. We found grim as a chief proapoptotic gene and skl and rpr as minor ones. The function of grim is also required for PCD of the mitotic sibling cells of the vCrz neuronal precursors (EW3-sib) during embryonic neurogenesis. An intergenic region between grim and rpr, which, it has been suggested, may enhance expression of three death genes in embryonic neuroblasts, appears to play a role for the vCrz PCD, but not for the EW3-sib cell death. The death of vCrz neurons and EW3-sib is triggered by ecdysone and the Notch signaling pathway, respectively, suggesting distinct regulatory mechanisms of grim expression in a cell- and developmental stage-specific manner.

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Dopamine D2 Receptor as a Cellular Component Controlling Nocturnal Hyperactivities inDrosophila melanogaster

Lee

Kikuno

Bahn

et al. 2013

Chronobiology International

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Dysfunctional regulation of brain dopamine (DA) functions has been found in patients with drug addiction and various neurological disorders that frequently accompany disturbance in sleep behavior. In this study, the roles of the dopaminergic nervous system on the regulation of daily locomotor activity rhythm were investigated in Drosophila melanogaster. Reduced synaptic DA release by expressing tetanus toxin gradually attenuated peak activity levels by altering activity patterns, particularly under constant darkness. Besides, flies with a mutant dopamine transporter fumin (fmn), in which the synaptic DA levels were elevated, displayed increased activities in both daytime and nighttime, but did more so at nighttime, suggesting that DA function is involved in regulation of fruit fly's nocturnal locomotor activities. Furthermore, flies treated with bromocriptine, an agonist of Drosophila dopamine D2 receptor (dD2R), exhibited nocturnal locomotor hyperactivity in a dose-dependent manner and this effect was inhibited in dD2R knockdown flies. When mutant flies null for period (per), timeless (tim), dClock (dClk), or cycle (cyc) were treated with bromocriptine, only cycle-null flies (cyc(01)) did not show induced nocturnal hyperactivities, suggesting that cyc might play a role in bromocriptine-induced nocturnal hyperactivities. Elevation of experimental temperature also increased nocturnal activities at the expense of daytime activities. The heat-induced increase in nocturnal activities gradually returned to basal levels at continuously elevated temperature. Inhibition of DA synthesis did not suppress heat-induced early development of nocturnal hyperactivity but prevented gradual decrement of initially elevated nocturnal activities, suggesting that DA impinges on certain adaptive roles in response to changes in environmental temperature. These results overall suggest that controlling dopaminergic transmission is important for daily locomotor behavior and bromocriptine-induced nocturnal hyperactivity which is mediated through dD2R receptor and CYC functions. In parallel to these results, excessive activation of dopaminergic neurotransmission, the primary cause of schizophrenia, is associated with abnormally elevated nocturnal locomotor activities through D2-type receptor in Drosophila. The results suggest that fruit flies are an excellent model system to provide some answers to previously unexplainable observations regarding the compromised dopaminergic nervous system and the related therapeutic agents.

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Keiko Kikuno

Developmental regulation and functions of the expression of the neuropeptide corazonin in Drosophila melanogaster

Drosophila caspases involved in developmentally regulated programmed cell death of peptidergic neurons during early metamorphosis

Mechanisms of Postecdysis‐Associated Programmed Cell Death of Peptidergic Neurons in Drosophila melanogaster

Essential role of grim-led programmed cell death for the establishment of corazonin-producing peptidergic nervous system during embryogenesis and metamorphosis in Drosophila melanogaster

Dopamine D2 Receptor as a Cellular Component Controlling Nocturnal Hyperactivities inDrosophila melanogaster

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