Ingrid Hums scite author profile

In animal locomotion a tradeoff exists between stereotypy and flexibility: fast long-distance travelling (LDT) requires coherent regular motions, while local sampling and area-restricted search (ARS) rely on flexible movements. We report here on a posture control system in C. elegans that coordinates these needs. Using quantitative posture analysis we explain worm locomotion as a composite of two modes: regular undulations versus flexible turning. Graded reciprocal regulation of both modes allows animals to flexibly adapt their locomotion strategy under sensory stimulation along a spectrum ranging from LDT to ARS. Using genetics and functional imaging of neural activity we characterize the counteracting interneurons AVK and DVA that utilize FLP-1 and NLP-12 neuropeptides to control both motor modes. Gradual regulation of behaviors via this system is required for spatial navigation during chemotaxis. This work shows how a nervous system controls simple elementary features of posture to generate complex movements for goal-directed locomotion strategies.DOI: http://dx.doi.org/10.7554/eLife.14116.001

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EGL-13/SoxD Specifies Distinct O2 and CO2 Sensory Neuron Fates in Caenorhabditis elegans

Petersen

Romanos

Juozaityte

et al. 2013

PLoS Genet

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Animals harbor specialized neuronal systems that are used for sensing and coordinating responses to changes in oxygen (O2) and carbon dioxide (CO2). In Caenorhabditis elegans, the O2/CO2 sensory system comprises functionally and morphologically distinct sensory neurons that mediate rapid behavioral responses to exquisite changes in O2 or CO2 levels via different sensory receptors. How the diversification of the O2- and CO2-sensing neurons is established is poorly understood. We show here that the molecular identity of both the BAG (O2/CO2-sensing) and the URX (O2-sensing) neurons is controlled by the phylogenetically conserved SoxD transcription factor homolog EGL-13. egl-13 mutant animals fail to fully express the distinct terminal gene batteries of the BAG and URX neurons and, as such, are unable to mount behavioral responses to changes in O2 and CO2. We found that the expression of egl-13 is regulated in the BAG and URX neurons by two conserved transcription factors—ETS-5(Ets factor) in the BAG neurons and AHR-1(bHLH factor) in the URX neurons. In addition, we found that EGL-13 acts in partially parallel pathways with both ETS-5 and AHR-1 to direct BAG and URX neuronal fate respectively. Finally, we found that EGL-13 is sufficient to induce O2- and CO2-sensing cell fates in some cellular contexts. Thus, the same core regulatory factor, egl-13, is required and sufficient to specify the distinct fates of O2- and CO2-sensing neurons in C. elegans. These findings extend our understanding of mechanisms of neuronal diversification and the regulation of molecular factors that may be conserved in higher organisms.

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Correction: EGL-13/SoxD Specifies Distinct O₂and CO₂Sensory Neuron Fates in Caenorhabditis elegans

Petersen¹,

Romanos²,

Juozaityte³

et al. 2013

PLoS Genet

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Animals harbor specialized neuronal systems that are used for sensing and coordinating responses to changes in oxygen (O 2 ) and carbon dioxide (CO 2 ). In Caenorhabditis elegans, the O 2 /CO 2 sensory system comprises functionally and morphologically distinct sensory neurons that mediate rapid behavioral responses to exquisite changes in O 2 or CO 2 levels via different sensory receptors. How the diversification of the O 2 -and CO 2 -sensing neurons is established is poorly understood. We show here that the molecular identity of both the BAG (O 2 /CO 2 -sensing) and the URX (O 2 -sensing) neurons is controlled by the phylogenetically conserved SoxD transcription factor homolog EGL-13. egl-13 mutant animals fail to fully express the distinct terminal gene batteries of the BAG and URX neurons and, as such, are unable to mount behavioral responses to changes in O 2 and CO 2 . We found that the expression of egl-13 is regulated in the BAG and URX neurons by two conserved transcription factors-ETS-5(Ets factor) in the BAG neurons and AHR-1(bHLH factor) in the URX neurons. In addition, we found that EGL-13 acts in partially parallel pathways with both ETS-5 and AHR-1 to direct BAG and URX neuronal fate respectively. Finally, we found that EGL-13 is sufficient to induce O 2 -and CO 2 -sensing cell fates in some cellular contexts. Thus, the same core regulatory factor, egl-13, is required and sufficient to specify the distinct fates of O 2and CO 2 -sensing neurons in C. elegans. These findings extend our understanding of mechanisms of neuronal diversification and the regulation of molecular factors that may be conserved in higher organisms.

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Author response: Regulation of two motor patterns enables the gradual adjustment of locomotion strategy in Caenorhabditis elegans

Hums

Riedl

Mende

et al. 2016

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In animal locomotion a tradeoff exists between stereotypy and flexibility: fast longdistance travelling (LDT) requires coherent regular motions, while local sampling and area-restricted search (ARS) rely on flexible movements. We report here on a posture control system in C. elegans that coordinates these needs. Using quantitative posture analysis we explain worm locomotion as a composite of two modes: regular undulations versus flexible turning. Graded reciprocal regulation of both modes allows animals to flexibly adapt their locomotion strategy under sensory stimulation along a spectrum ranging from LDT to ARS. Using genetics and functional imaging of neural activity we characterize the counteracting interneurons AVK and DVA that utilize FLP-1 and NLP-12 neuropeptides to control both motor modes. Gradual regulation of behaviors via this system is required for spatial navigation during chemotaxis. This work shows how a nervous system controls simple elementary features of posture to generate complex movements for goal-directed locomotion strategies.

show abstract

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Ingrid Hums

Regulation of two motor patterns enables the gradual adjustment of locomotion strategy in Caenorhabditis elegans

EGL-13/SoxD Specifies Distinct O2 and CO2 Sensory Neuron Fates in Caenorhabditis elegans

Correction: EGL-13/SoxD Specifies Distinct O₂and CO₂Sensory Neuron Fates in Caenorhabditis elegans

Author response: Regulation of two motor patterns enables the gradual adjustment of locomotion strategy in Caenorhabditis elegans

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Ingrid Hums

Regulation of two motor patterns enables the gradual adjustment of locomotion strategy in Caenorhabditis elegans

EGL-13/SoxD Specifies Distinct O2 and CO2 Sensory Neuron Fates in Caenorhabditis elegans

Correction: EGL-13/SoxD Specifies Distinct O2and CO2Sensory Neuron Fates in Caenorhabditis elegans

Author response: Regulation of two motor patterns enables the gradual adjustment of locomotion strategy in Caenorhabditis elegans

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Correction: EGL-13/SoxD Specifies Distinct O₂and CO₂Sensory Neuron Fates in Caenorhabditis elegans