Active propagation of dendritic electrical signals in C. elegans

Shindou, Tomomi; Ochi-Shindou, Mayumi; Murayama, Takashi; Saita, Ei-ichiro; Momohara, Yuto; Wickens, Jeffery R.; Maruyama, Ichiro

doi:10.1038/s41598-019-40158-9

Cited by 18 publications

(35 citation statements)

References 62 publications

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“…elegans , Ca 2+ is thought to be the main charge carrier in membrane-potential changes, due to the lack of voltage-gated Na + channels in its neurons (Faumont et al., 2011, Faumont et al., 2006, Gao and Zhen, 2011, Goodman et al., 1998, Mellem et al., 2008, Shidara et al., 2013). Recently, the relationship between membrane potential and Ca 2+ channels has been thoroughly investigated, and it has been shown that Ca 2+ channels are necessary for membrane-potential spikes (Liu et al., 2018, Shindou et al., 2019). Ca 2+ responses in AIY regulate the animal's behavior (Li et al., 2014), so the results of information processing should be expressed as membrane-potential changes.…”

Section: Resultsmentioning

confidence: 99%

“…This indicates that AIY neurons retain the function of Ca 2+ spike generation even without glutamate inputs. This suggests that the AIY neurons should have maintained their equilibrium potential even in the mutant animals because depolarization is necessary for generating Ca 2+ spikes (Liu et al., 2018, Shindou et al., 2019). In the mutants, glutamate inputs could not cause the depolarization of membrane potential beyond the threshold in response to environmental fluctuations by glutamate inputs, so the Ca 2+ spike frequency decreased.…”

Section: Discussionmentioning

confidence: 99%

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The Input-Output Relationship of AIY Interneurons in Caenorhabditis elegans in Noisy Environment

2019

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Summary Determining how neurotransmitter input causes various neuronal activities is crucial to understanding neuronal information processing. In Caenorhabditis elegans , AIY interneurons receive several sources of sensory information as glutamate inputs and regulate behavior by integrating these inputs. However, the relationship between glutamate input and the Ca 2+ response in AIY under environmental noise, in other words, without explicit stimulation, remains unknown. Here, we show that glutamate-input fluctuations evoke a sporadic Ca 2+ response in AIY without stimulation. To ensure that Ca 2+ response can be considered AIY output, we show that the membrane-potential depolarization precedes Ca 2+ responses in AIY. We used an odor as model stimulation to modulate the sensory inputs. Simultaneous imaging of glutamate input and Ca 2+ response, together with glutamate transmission mutants, showed that glutamate-input fluctuations evoke sporadic Ca 2+ responses. We identified the input-output relationships under environmental noise in vivo , and our results address the relationship between sensory-input fluctuations and behavioral variability.

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Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

The Input-Output Relationship of AIY Interneurons in Caenorhabditis elegans in Noisy Environment

2019

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“…These cGMP dynamics were observed specifically at sensory endings but not at soma, which was in contrast to Ca2+ dynamics that are uniform among subcompartments in AFD such as sensory ending, dendrite, soma and axon. Given that GCYs and TAX-2 and TAX-4 CNG channels localize at the sensory ending in AFD and that Ca2+ dynamics are uniform all over AFD, there is supposed to be a mechanism that propagates Ca2+ increase from the sensory endings (Shindou et al, 2019). We also found that the cGMP dynamics, which are supposed to be upstream of Ca2+ dynamics, reflected the comparison between past cultivation temperature and present ambient temperature, indicating that AFD memorizes temperature by simpler molecular mechanisms than so far expected from the results of Ca2+ imaging and membrane potential recording.…”

Section: Discussionmentioning

confidence: 99%

cGMP dynamics underlie thermosensation in C. elegans

Aoki

Shiota

Nakano

et al. 2019

Preprint

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Animals sense ambient temperature so that they can adjust their behavior to the environment; they avoid noxious heat and coldness and stay within a survivable temperature range. C. elegans can sense temperature, memorize past cultivation temperature and navigate towards preferable temperature, for which a thermosensory neuron, AFD, is essential. AFD responds to temperature increase from the past cultivation temperature by increasing intracellular Ca2+ level. We aimed to reveal how AFD encodes and memorizes the information of temperature. Although cGMP synthesis is crucial for thermosensation by AFD, whether and how cGMP level temporally fluctuates in AFD remained elusive. We therefore monitored cGMP level in AFD and found that cGMP dynamically responded to temperature change in a manner dependent on past cultivation temperature. Given that cGMP dynamics is supposed to be upstream of Ca2+ dynamics, our results suggest that AFD's memory is formed by simpler molecular mechanisms than previously expected from the Ca2+ dynamics. Moreover, we analyzed how guanylyl cyclases and phosphodiesterases, which synthesize and degrade cGMP, respectively, contributed to cGMP and Ca2+ dynamics and thermotaxis behavior.(175 words)

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“…Being known as electrical synapses (Bennett 1997), gap junctions can synchronise electrical activities of the coupled neurons (Bennett and Zukin 2004). While neuronal and, to a lesser extent, sub-circuit functions have been extensively studied in C. elegans (Guo et al 2015;Larsch et al 2013;Liu et al 2018;Shindou et al 2019;Suzuki et al 2008), these have almost exclusively been limited to either the left or right side of the body, limiting our understanding of symmetry and asymmetry in sensory responses and information flow. With the exception of whole-brain imaging studies (Nguyen et al 2016;Schrödel et al 2013;Tobin et al 2002), imaging one or more pairs of bilateral neurons simultaneously has largely been avoided since, in most experiments, the animal lies on its left or right side, such that the two cells are not located in the same focal plane of the microscope (Chokshi et al 2010;Chronis et al 2007;Gordus et al 2015;Larsch et al 2015).…”

Section: Introductionmentioning

confidence: 99%

Rotatable microfluidic device for simultaneous study of bilateral chemosensory neurons in Caenorhabditis elegans

Chung

Brittin

Evans

et al. 2020

Microfluid Nanofluid

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The nematode Caenorhabditis elegans is a leading model system in genetics, development and neurobiology; its transparent body and small size make it particularly suitable for fluorescent imaging of cells and neurons within microfluidic setups. Simultaneously recording activity in bilaterally symmetric cells has proved difficult in C. elegans because the worm enters the chip and is then immobilised when it is lying on one side of the body. We developed a side-view rotatable microfluidic device that allows us to image a pair of bilateral neurons in a single focal plane of an epi-fluorescence microscope. We demonstrated the utility of the device by recording the responses of immobilised worms to controlled stimuli, focusing on the responses of two classes of head sensory neurons to changes in NaCl concentration. The results indicate that responses of ASE left and right and ASH left and right sensory neurons are stochastic. Simultaneous recordings of ASH left and right neurons tend to synchronise, pointing to a role of gap junctional connectivity. The anatomy of the C. elegans nerve ring makes this microfluidic approach ideally suited for the study of spatially extended pairs of neurons or larger neuronal circuits that lie within a limited depth of field.

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Active propagation of dendritic electrical signals in C. elegans

Cited by 18 publications

References 62 publications

The Input-Output Relationship of AIY Interneurons in Caenorhabditis elegans in Noisy Environment

The Input-Output Relationship of AIY Interneurons in Caenorhabditis elegans in Noisy Environment

cGMP dynamics underlie thermosensation in C. elegans

Rotatable microfluidic device for simultaneous study of bilateral chemosensory neurons in Caenorhabditis elegans

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