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1.
Cell ; 185(26): 5011-5027.e20, 2022 12 22.
Artigo em Inglês | MEDLINE | ID: mdl-36563666

RESUMO

To track and control self-location, animals integrate their movements through space. Representations of self-location are observed in the mammalian hippocampal formation, but it is unknown if positional representations exist in more ancient brain regions, how they arise from integrated self-motion, and by what pathways they control locomotion. Here, in a head-fixed, fictive-swimming, virtual-reality preparation, we exposed larval zebrafish to a variety of involuntary displacements. They tracked these displacements and, many seconds later, moved toward their earlier location through corrective swimming ("positional homeostasis"). Whole-brain functional imaging revealed a network in the medulla that stores a memory of location and induces an error signal in the inferior olive to drive future corrective swimming. Optogenetically manipulating medullary integrator cells evoked displacement-memory behavior. Ablating them, or downstream olivary neurons, abolished displacement corrections. These results reveal a multiregional hindbrain circuit in vertebrates that integrates self-motion and stores self-location to control locomotor behavior.


Assuntos
Neurônios , Peixe-Zebra , Animais , Peixe-Zebra/fisiologia , Neurônios/fisiologia , Rombencéfalo/fisiologia , Encéfalo/fisiologia , Natação/fisiologia , Homeostase , Mamíferos
2.
Cell ; 167(4): 933-946.e20, 2016 11 03.
Artigo em Inglês | MEDLINE | ID: mdl-27881303

RESUMO

To execute accurate movements, animals must continuously adapt their behavior to changes in their bodies and environments. Animals can learn changes in the relationship between their locomotor commands and the resulting distance moved, then adjust command strength to achieve a desired travel distance. It is largely unknown which circuits implement this form of motor learning, or how. Using whole-brain neuronal imaging and circuit manipulations in larval zebrafish, we discovered that the serotonergic dorsal raphe nucleus (DRN) mediates short-term locomotor learning. Serotonergic DRN neurons respond phasically to swim-induced visual motion, but little to motion that is not self-generated. During prolonged exposure to a given motosensory gain, persistent DRN activity emerges that stores the learned efficacy of motor commands and adapts future locomotor drive for tens of seconds. The DRN's ability to track the effectiveness of motor intent may constitute a computational building block for the broader functions of the serotonergic system. VIDEO ABSTRACT.


Assuntos
Aprendizagem , Modelos Neurológicos , Natação , Peixe-Zebra/fisiologia , Animais , Mapeamento Encefálico , Larva , Optogenética , Núcleos da Rafe/fisiologia , Neurônios Serotoninérgicos/citologia , Neurônios Serotoninérgicos/fisiologia , Processamento Espacial
3.
Proc Natl Acad Sci U S A ; 110(40): E3878-87, 2013 Oct 01.
Artigo em Inglês | MEDLINE | ID: mdl-24043825

RESUMO

As animals grow, their nervous systems also increase in size. How growth in the central nervous system is regulated and its functional consequences are incompletely understood. We explored these questions, using the larval Drosophila locomotor system as a model. In the periphery, at neuromuscular junctions, motoneurons are known to enlarge their presynaptic axon terminals in size and strength, thereby compensating for reductions in muscle excitability that are associated with increases in muscle size. Here, we studied how motoneurons change in the central nervous system during periods of animal growth. We find that within the central nervous system motoneurons also enlarge their postsynaptic dendritic arbors, by the net addition of branches, and that these scale with overall animal size. This dendritic growth is gated on a cell-by-cell basis by a specific isoform of the steroid hormone receptor ecdysone receptor-B2, for which functions have thus far remained elusive. The dendritic growth is accompanied by synaptic strengthening and results in increased neuronal activity. Electrical properties of these neurons, however, are independent of ecdysone receptor-B2 regulation. We propose that these structural dendritic changes in the central nervous system, which regulate neuronal activity, constitute an additional part of the adaptive response of the locomotor system to increases in body and muscle size as the animal grows.


Assuntos
Adaptação Biológica/fisiologia , Tamanho Corporal/fisiologia , Sistema Nervoso Central/crescimento & desenvolvimento , Dendritos/fisiologia , Drosophila/fisiologia , Locomoção/fisiologia , Neurônios Motores/citologia , Análise de Variância , Animais , Imuno-Histoquímica , Larva/crescimento & desenvolvimento , Receptores de Esteroides/metabolismo , Estatísticas não Paramétricas
4.
J Neurosci ; 33(25): 10384-95, 2013 Jun 19.
Artigo em Inglês | MEDLINE | ID: mdl-23785151

RESUMO

The RNA-binding protein Hermes [RNA-binding protein with multiple splicing (RBPMS)] is expressed exclusively in retinal ganglion cells (RGCs) in the CNS, but its function in these cells is not known. Here we show that Hermes protein translocates in granules from RGC bodies down the growing axons. Hermes loss of function in both Xenopus laevis and zebrafish embryos leads to a significant reduction in retinal axon arbor complexity in the optic tectum, and expression of a dominant acting mutant Hermes protein, defective in RNA-granule localization, causes similar defects in arborization. Time-lapse analysis of branch dynamics reveals that the decrease in arbor complexity is caused by a reduction in new branches rather than a decrease in branch stability. Surprisingly, Hermes depletion also leads to enhanced early visual behavior and an increase in the density of presynaptic puncta, suggesting that reduced arborization is accompanied by increased synaptogenesis to maintain synapse number.


Assuntos
Axônios/fisiologia , Proteínas de Ligação a RNA/fisiologia , Células Ganglionares da Retina/fisiologia , Sinapses/fisiologia , Proteínas de Xenopus/fisiologia , Animais , Comportamento Animal/fisiologia , Western Blotting , Diferenciação Celular/fisiologia , Células Cultivadas , DNA/genética , Eletroporação , Embrião não Mamífero , Feminino , Homeostase/fisiologia , Imuno-Histoquímica , Hibridização In Situ , Masculino , Microscopia Confocal , Plasmídeos/genética , RNA Mensageiro/biossíntese , RNA Mensageiro/genética , Retina/crescimento & desenvolvimento , Retina/fisiologia , Visão Ocular/fisiologia , Xenopus , Peixe-Zebra/fisiologia
5.
bioRxiv ; 2024 Jun 17.
Artigo em Inglês | MEDLINE | ID: mdl-38948859

RESUMO

Understanding how animals coordinate movements to achieve goals is a fundamental pursuit in neuroscience. Here we explore how neurons that reside in posterior lower-order regions of a locomotor system project to anterior higher-order regions to influence steering and navigation. We characterized the anatomy and functional role of a population of ascending interneurons in the ventral nerve cord of Drosophila larvae. Through electron microscopy reconstructions and light microscopy, we determined that the cholinergic 19f cells receive input primarily from premotor interneurons and synapse upon a diverse array of postsynaptic targets within the anterior segments including other 19f cells. Calcium imaging of 19f activity in isolated central nervous system (CNS) preparations in relation to motor neurons revealed that 19f neurons are recruited into most larval motor programmes. 19f activity lags behind motor neuron activity and as a population, the cells encode spatio-temporal patterns of locomotor activity in the larval CNS. Optogenetic manipulations of 19f cell activity in isolated CNS preparations revealed that they coordinate the activity of central pattern generators underlying exploratory headsweeps and forward locomotion in a context and location specific manner. In behaving animals, activating 19f cells suppressed exploratory headsweeps and slowed forward locomotion, while inhibition of 19f activity potentiated headsweeps, slowing forward movement. Inhibiting activity in 19f cells ultimately affected the ability of larvae to remain in the vicinity of an odor source during an olfactory navigation task. Overall, our findings provide insights into how ascending interneurons monitor motor activity and shape interactions amongst rhythm generators underlying complex navigational tasks.

6.
Proc Natl Acad Sci U S A ; 107(49): 21040-5, 2010 Dec 07.
Artigo em Inglês | MEDLINE | ID: mdl-21078992

RESUMO

Olfactory ensheathing cells (OECs) are a unique class of glial cells with exceptional translational potential because of their ability to support axon regeneration in the central nervous system. Although OECs are similar in many ways to immature and nonmyelinating Schwann cells, and can myelinate large-diameter axons indistinguishably from myelination by Schwann cells, current dogma holds that OECs arise from the olfactory epithelium. Here, using fate-mapping techniques in chicken embryos and genetic lineage tracing in mice, we show that OECs in fact originate from the neural crest and hence share a common developmental heritage with Schwann cells. This explains the similarities between OECs and Schwann cells and overturns the existing dogma on the developmental origin of OECs. Because neural crest stem cells persist in adult tissue, including skin and hair follicles, our results also raise the possibility that patient-derived neural crest stem cells could in the future provide an abundant and accessible source of autologous OECs for cell transplantation therapy for the injured central nervous system.


Assuntos
Linhagem da Célula , Crista Neural/citologia , Neuroglia/citologia , Mucosa Olfatória/citologia , Animais , Transplante de Células , Embrião de Galinha , Técnicas Citológicas , Humanos , Camundongos , Medicina Regenerativa/métodos , Células de Schwann
7.
Elife ; 122023 08 08.
Artigo em Inglês | MEDLINE | ID: mdl-37551094

RESUMO

The ability to adjust the speed of locomotion is essential for survival. In limbed animals, the frequency of locomotion is modulated primarily by changing the duration of the stance phase. The underlying neural mechanisms of this selective modulation remain an open question. Here, we report a neural circuit controlling a similarly selective adjustment of locomotion frequency in Drosophila larvae. Drosophila larvae crawl using peristaltic waves of muscle contractions. We find that larvae adjust the frequency of locomotion mostly by varying the time between consecutive contraction waves, reminiscent of limbed locomotion. A specific set of muscles, the lateral transverse (LT) muscles, co-contract in all segments during this phase, the duration of which sets the duration of the interwave phase. We identify two types of GABAergic interneurons in the LT neural network, premotor neuron A26f and its presynaptic partner A31c, which exhibit segmentally synchronized activity and control locomotor frequency by setting the amplitude and duration of LT muscle contractions. Altogether, our results reveal an inhibitory central circuit that sets the frequency of locomotion by controlling the duration of the period in between peristaltic waves. Further analysis of the descending inputs onto this circuit will help understand the higher control of this selective modulation.


Assuntos
Drosophila , Neurônios Motores , Animais , Drosophila/fisiologia , Larva/fisiologia , Neurônios Motores/fisiologia , Contração Muscular , Locomoção/fisiologia
8.
Adv Physiol Educ ; 35(4): 384-92, 2011 Dec.
Artigo em Inglês | MEDLINE | ID: mdl-22139775

RESUMO

Invertebrate model organisms are powerful systems for uncovering conserved principles of animal biology. Despite widespread use in scientific communities, invertebrate research is often severely undervalued by laypeople. Here, we present a set of simple, inexpensive public outreach exercises aimed at explaining to the public why basic research on one particular invertebrate, the insect Drosophila melanogaster, is valuable. First, we designed seven teaching modules that highlight cutting-edge research in Drosophila genetics, metabolism, physiology, and behavior. We then implemented these exercises in a public outreach event that included both children and adults. Quantitative evaluation of participant feedback suggests that these exercises 1) teach principles of animal biology, 2) help laypeople better understand why researchers study fruit flies, and 3) are effective over a wide range of age groups. Overall, this work provides a blueprint for how to use Drosophila as a vehicle for increasing public awareness and appreciation of basic research on genetically tractable insects in particular and invertebrates in general.


Assuntos
Pesquisa Biomédica/métodos , Relações Comunidade-Instituição , Drosophila melanogaster/fisiologia , Opinião Pública , Adulto , Animais , Recursos Audiovisuais , Conscientização , Comportamento Animal , Criança , Comunicação , Relações Comunidade-Instituição/economia , Compreensão , Drosophila melanogaster/genética , Drosophila melanogaster/metabolismo , Humanos , Modelos Animais , Percepção , Avaliação de Programas e Projetos de Saúde , Inquéritos e Questionários
9.
Curr Biol ; 16(11): 1090-5, 2006 Jun 06.
Artigo em Inglês | MEDLINE | ID: mdl-16753562

RESUMO

The Drosophila anterior-posterior axis is established at stage 7 of oogenesis when the posterior follicle cells signal to polarize the oocyte microtubule cytoskeleton. This requires the conserved PAR-1 kinase, which can be detected at the posterior of the oocyte in immunostainings from stage 9. However, this localization depends on Oskar localization, which requires the earlier PAR-1-dependent microtubule reorganization, indicating that Oskar-associated PAR-1 cannot establish oocyte polarity. Here we analyze the function of the different PAR-1 isoforms and find that only PAR-1 N1 isoforms can completely rescue the oocyte polarity phenotype. Furthermore, PAR-1 N1 is recruited to the posterior cortex of the oocyte at stage 7 in response to the polarizing follicle cell signal, and this requires actin, but not microtubules. This suggests that posterior PAR-1 N1 polarizes the microtubule cytoskeleton. PAR-1 N1 localization is mediated by a cortical targeting domain and a conserved anterior-lateral exclusion signal in its C-terminal linker domain. PAR-1 is also required for the polarization of the C. elegans zygote and is recruited to the posterior cortex in an actin-dependent manner. Our results therefore identify a molecular parallel between axis formation in Drosophila and C. elegans and make Drosophila PAR-1 N1 the earliest known marker for the polarization of the oocyte.


Assuntos
Actinas/fisiologia , Padronização Corporal/fisiologia , Proteínas de Drosophila/fisiologia , Drosophila/enzimologia , Drosophila/crescimento & desenvolvimento , Oócitos/enzimologia , Proteínas Quinases/fisiologia , Actinas/metabolismo , Sequência de Aminoácidos , Animais , Caenorhabditis elegans/crescimento & desenvolvimento , Caenorhabditis elegans/metabolismo , Sequência Conservada , Drosophila/genética , Proteínas de Drosophila/análise , Proteínas de Drosophila/química , Quinase 3 da Glicogênio Sintase , Microtúbulos/metabolismo , Dados de Sequência Molecular , Oócitos/citologia , Oócitos/crescimento & desenvolvimento , Isoformas de Proteínas/análise , Isoformas de Proteínas/química , Isoformas de Proteínas/metabolismo , Proteínas Quinases/análise , Proteínas Quinases/química , Proteínas Serina-Treonina Quinases , Estrutura Terciária de Proteína , Proteínas Recombinantes de Fusão/análise
10.
Nat Commun ; 10(1): 2654, 2019 06 14.
Artigo em Inglês | MEDLINE | ID: mdl-31201326

RESUMO

Animal locomotion requires spatiotemporally coordinated contraction of muscles throughout the body. Here, we investigate how contractions of antagonistic groups of muscles are intersegmentally coordinated during bidirectional crawling of Drosophila larvae. We identify two pairs of higher-order premotor excitatory interneurons present in each abdominal neuromere that intersegmentally provide feedback to the adjacent neuromere during motor propagation. The two feedback neuron pairs are differentially active during either forward or backward locomotion but commonly target a group of premotor interneurons that together provide excitatory inputs to transverse muscles and inhibitory inputs to the antagonistic longitudinal muscles. Inhibition of either feedback neuron pair compromises contraction of transverse muscles in a direction-specific manner. Our results suggest that the intersegmental feedback neurons coordinate contraction of synergistic muscles by acting as delay circuits representing the phase lag between segments. The identified circuit architecture also shows how bidirectional motor networks could be economically embedded in the nervous system.


Assuntos
Retroalimentação Fisiológica , Locomoção/fisiologia , Rede Nervosa/fisiologia , Animais , Animais Geneticamente Modificados , Proteínas de Drosophila/genética , Drosophila melanogaster/fisiologia , Interneurônios/fisiologia , Larva/fisiologia , Microscopia Eletrônica , Modelos Animais , Contração Muscular/fisiologia , Músculos/inervação , Músculos/fisiologia , Optogenética
11.
Elife ; 72018 12 17.
Artigo em Inglês | MEDLINE | ID: mdl-30540251

RESUMO

Reactive oxygen species (ROS) have been extensively studied as damaging agents associated with ageing and neurodegenerative conditions. Their role in the nervous system under non-pathological conditions has remained poorly understood. Working with the Drosophila larval locomotor network, we show that in neurons ROS act as obligate signals required for neuronal activity-dependent structural plasticity, of both pre- and postsynaptic terminals. ROS signaling is also necessary for maintaining evoked synaptic transmission at the neuromuscular junction, and for activity-regulated homeostatic adjustment of motor network output, as measured by larval crawling behavior. We identified the highly conserved Parkinson's disease-linked protein DJ-1ß as a redox sensor in neurons where it regulates structural plasticity, in part via modulation of the PTEN-PI3Kinase pathway. This study provides a new conceptual framework of neuronal ROS as second messengers required for neuronal plasticity and for network tuning, whose dysregulation in the ageing brain and under neurodegenerative conditions may contribute to synaptic dysfunction.


Assuntos
Drosophila melanogaster/metabolismo , Neurônios Motores/metabolismo , Plasticidade Neuronal , Espécies Reativas de Oxigênio/metabolismo , Animais , Animais Geneticamente Modificados , Proteínas de Drosophila/metabolismo , Drosophila melanogaster/genética , Larva/genética , Larva/metabolismo , Microscopia Eletrônica de Transmissão , Proteínas do Tecido Nervoso/metabolismo , Junção Neuromuscular/metabolismo , Junção Neuromuscular/ultraestrutura , PTEN Fosfo-Hidrolase/metabolismo , Fosfatidilinositol 3-Quinases/metabolismo , Terminações Pré-Sinápticas/metabolismo , Terminações Pré-Sinápticas/ultraestrutura , Proteína Desglicase DJ-1 , Transdução de Sinais , Transmissão Sináptica
12.
Elife ; 52016 Feb 15.
Artigo em Inglês | MEDLINE | ID: mdl-26880545

RESUMO

Animals move by adaptively coordinating the sequential activation of muscles. The circuit mechanisms underlying coordinated locomotion are poorly understood. Here, we report on a novel circuit for the propagation of waves of muscle contraction, using the peristaltic locomotion of Drosophila larvae as a model system. We found an intersegmental chain of synaptically connected neurons, alternating excitatory and inhibitory, necessary for wave propagation and active in phase with the wave. The excitatory neurons (A27h) are premotor and necessary only for forward locomotion, and are modulated by stretch receptors and descending inputs. The inhibitory neurons (GDL) are necessary for both forward and backward locomotion, suggestive of different yet coupled central pattern generators, and its inhibition is necessary for wave propagation. The circuit structure and functional imaging indicated that the commands to contract one segment promote the relaxation of the next segment, revealing a mechanism for wave propagation in peristaltic locomotion.


Assuntos
Drosophila melanogaster/fisiologia , Locomoção , Contração Muscular , Rede Nervosa/fisiologia , Potenciais de Ação , Animais , Larva/fisiologia , Neurônios Motores/fisiologia , Imagem Óptica
13.
Neuron ; 91(3): 615-28, 2016 Aug 03.
Artigo em Inglês | MEDLINE | ID: mdl-27427461

RESUMO

Locomotor systems generate diverse motor patterns to produce the movements underlying behavior, requiring that motor neurons be recruited at various phases of the locomotor cycle. Reciprocal inhibition produces alternating motor patterns; however, the mechanisms that generate other phasic relationships between intrasegmental motor pools are unknown. Here, we investigate one such motor pattern in the Drosophila larva, using a multidisciplinary approach including electrophysiology and ssTEM-based circuit reconstruction. We find that two motor pools that are sequentially recruited during locomotion have identical excitable properties. In contrast, they receive input from divergent premotor circuits. We find that this motor pattern is not orchestrated by differential excitatory input but by a GABAergic interneuron acting as a delay line to the later-recruited motor pool. Our findings show how a motor pattern is generated as a function of the modular organization of locomotor networks through segregation of inhibition, a potentially general mechanism for sequential motor patterns.


Assuntos
Drosophila melanogaster , Neurônios Motores/fisiologia , Inibição Neural/fisiologia , Vias Neurais/fisiologia , Animais , Drosophila melanogaster/citologia , Drosophila melanogaster/fisiologia , Neurônios GABAérgicos/fisiologia , Interneurônios/fisiologia , Larva/citologia , Larva/fisiologia , Locomoção/fisiologia
14.
Elife ; 52016 Mar 18.
Artigo em Inglês | MEDLINE | ID: mdl-26990779

RESUMO

Neuronal circuit mapping using electron microscopy demands laborious proofreading or reconciliation of multiple independent reconstructions. Here, we describe new methods to apply quantitative arbor and network context to iteratively proofread and reconstruct circuits and create anatomically enriched wiring diagrams. We measured the morphological underpinnings of connectivity in new and existing reconstructions of Drosophila sensorimotor (larva) and visual (adult) systems. Synaptic inputs were preferentially located on numerous small, microtubule-free 'twigs' which branch off a single microtubule-containing 'backbone'. Omission of individual twigs accounted for 96% of errors. However, the synapses of highly connected neurons were distributed across multiple twigs. Thus, the robustness of a strong connection to detailed twig anatomy was associated with robustness to reconstruction error. By comparing iterative reconstruction to the consensus of multiple reconstructions, we show that our method overcomes the need for redundant effort through the discovery and application of relationships between cellular neuroanatomy and synaptic connectivity.


Assuntos
Conectoma/métodos , Drosophila/anatomia & histologia , Drosophila/fisiologia , Animais , Sistema Nervoso/anatomia & histologia , Fenômenos Fisiológicos do Sistema Nervoso
15.
Neuron ; 88(2): 314-29, 2015 Oct 21.
Artigo em Inglês | MEDLINE | ID: mdl-26439528

RESUMO

Bilaterally symmetric motor patterns--those in which left-right pairs of muscles contract synchronously and with equal amplitude (such as breathing, smiling, whisking, and locomotion)--are widespread throughout the animal kingdom. Yet, surprisingly little is known about the underlying neural circuits. We performed a thermogenetic screen to identify neurons required for bilaterally symmetric locomotion in Drosophila larvae and identified the evolutionarily conserved Even-skipped(+) interneurons (Eve/Evx). Activation or ablation of Eve(+) interneurons disrupted bilaterally symmetric muscle contraction amplitude, without affecting the timing of motor output. Eve(+) interneurons are not rhythmically active and thus function independently of the locomotor CPG. GCaMP6 calcium imaging of Eve(+) interneurons in freely moving larvae showed left-right asymmetric activation that correlated with larval behavior. TEM reconstruction of Eve(+) interneuron inputs and outputs showed that the Eve(+) interneurons are at the core of a sensorimotor circuit capable of detecting and modifying body wall muscle contraction.


Assuntos
Proteínas de Drosophila/fisiologia , Lateralidade Funcional/fisiologia , Proteínas de Homeodomínio/fisiologia , Interneurônios/fisiologia , Contração Muscular/fisiologia , Rede Nervosa/fisiologia , Desempenho Psicomotor/fisiologia , Fatores de Transcrição/fisiologia , Animais , Animais Geneticamente Modificados , Interneurônios/química , Rede Nervosa/química
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