Skip to main content

Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

  • Brief Communication
  • Published:

TRP channel mediated neuronal activation and ablation in freely behaving zebrafish

Abstract

The zebrafish (Danio rerio) is a useful vertebrate model system in which to study neural circuits and behavior, but tools to modulate neurons in freely behaving animals are limited. As poikilotherms that live in water, zebrafish are amenable to thermal and pharmacological perturbations. We exploit these properties by using transient receptor potential (TRP) channels to activate or ablate specific neuronal populations using the chemical and thermal agonists of heterologously expressed TRPV1, TRPM8 and TRPA1.

This is a preview of subscription content, access via your institution

Access options

Buy this article

Prices may be subject to local taxes which are calculated during checkout

Figure 1: Csn induces locomotor and neuronal activity in embryos expressing TRPV1 in sensory neurons.
Figure 2: Csn dose-dependent ablation of TRPV1-expressing neurons.
Figure 3: TRPV1-mediated activation and ablation of Hcrt neurons affects sleep-wake behaviors.

Similar content being viewed by others

Accession codes

Accessions

NCBI Reference Sequence

References

  1. Fleming, A., Diekmann, H. & Goldsmith, P. PLoS ONE 8, e77548 (2013).

    Article  CAS  Google Scholar 

  2. Wolman, M. & Granato, M. Dev. Neurobiol. 72, 366–372 (2012).

    Article  CAS  Google Scholar 

  3. Friedrich, R.W. et al. Front. Neural Circuits 7, 71 (2013).

    Article  Google Scholar 

  4. Douglass, A.D., Kraves, S., Deisseroth, K., Schier, A.F. & Engert, F. Curr. Biol. 18, 1133–1137 (2008).

    Article  CAS  Google Scholar 

  5. Zhu, P. et al. Front. Neural Circuits 3, 21 (2009).

    Article  Google Scholar 

  6. Arenkiel, B.R., Klein, M.E., Davison, I.G., Katz, L.C. & Ehlers, M.D. Nat. Methods 5, 299–302 (2008).

    Article  CAS  Google Scholar 

  7. Alexander, G.M. et al. Neuron 63, 27–39 (2009).

    Article  CAS  Google Scholar 

  8. Magnus, C.J. et al. Science 333, 1292–1296 (2011).

    Article  CAS  Google Scholar 

  9. Hamada, F.N. et al. Nature 454, 217–220 (2008).

    Article  CAS  Google Scholar 

  10. Caterina, M.J. et al. Nature 389, 816–824 (1997).

    Article  CAS  Google Scholar 

  11. Peier, A.M. et al. Cell 108, 705–715 (2002).

    Article  CAS  Google Scholar 

  12. Gracheva, E.O. et al. Nature 464, 1006–1011 (2010).

    Article  CAS  Google Scholar 

  13. Gau, P. et al. J. Neurosci. 33, 5249–5260 (2013).

    Article  CAS  Google Scholar 

  14. Prober, D.A. et al. J. Neurosci. 28, 10102–10110 (2008).

    Article  CAS  Google Scholar 

  15. Liu, J. et al. Development 142, 1113–1124 (2015).

    Article  CAS  Google Scholar 

  16. Prober, D.A., Rihel, J., Onah, A.A., Sung, R.J. & Schier, A.F. J. Neurosci. 26, 13400–13410 (2006).

    Article  CAS  Google Scholar 

  17. Elbaz, I., Yelin-Bekerman, L., Nicenboim, J., Vatine, G. & Appelbaum, L. J. Neurosci. 32, 12961–12972 (2012).

    Article  CAS  Google Scholar 

  18. Bernstein, J.G., Garrity, P.A. & Boyden, E.S. Curr. Opin. Neurobiol. 22, 61–71 (2012).

    Article  CAS  Google Scholar 

  19. Mathias, J.R., Zhang, Z., Saxena, M.T. & Mumm, J.S. Zebrafish 11, 85–97 (2014).

    Article  CAS  Google Scholar 

  20. Tabor, K.M. et al. J. Neurophysiol. 112, 834–844 (2014).

    Article  Google Scholar 

  21. Jordt, S.E., Tominaga, M. & Julius, D. Proc. Natl. Acad. Sci. USA 97, 8134–8139 (2000).

    Article  CAS  Google Scholar 

  22. Shaner, N.C. et al. Nat. Methods 5, 545–551 (2008).

    Article  CAS  Google Scholar 

  23. Higashijima, S., Hotta, Y. & Okamoto, H. J. Neurosci. 20, 206–218 (2000).

    Article  CAS  Google Scholar 

  24. Köster, R.W. & Fraser, S.E. Dev. Biol. 233, 329–346 (2001).

    Article  Google Scholar 

  25. Faraco, J.H. et al. J. Biol. Chem. 281, 29753–29761 (2006).

    Article  CAS  Google Scholar 

  26. Kawakami, K. Dev. Dyn. 234, 244–254 (2005).

    Article  CAS  Google Scholar 

  27. Thermes, V. et al. Mech. Dev. 118, 91–98 (2002).

    Article  CAS  Google Scholar 

  28. Ahrens, M.B., Orger, M.B., Robson, D.N., Li, J.M. & Keller, P.J. Nat. Methods 10, 413–420 (2013).

    Article  CAS  Google Scholar 

  29. Scott, E.K. & Baier, H. Front. Neural Circuits 3, 13 (2009).

    Article  Google Scholar 

  30. Naumann, E.A., Kampff, A.R., Prober, D.A., Schier, A.F. & Engert, F. Nat. Neurosci. 13, 513–520 (2010).

    Article  CAS  Google Scholar 

Download references

Acknowledgements

We thank A. Chen, A. Cruz, A. Dominguez, J. Engle, S. Khan, K. Molinder, B. Niles, V. Sapin and L. Wang for technical assistance. This work was supported by grants from the US National Institutes of Health (F31-NS07842A to S.C.; F32-NS083099 to K.L.M.; R01-NS26539 and DP1-OD006411 to J.R.F.; R00-NS060996, R01-NS070911 and R01-DA031367 to D.A.P.) and the Mallinckrodt Foundation, the Rita Allen Foundation and the Brain and Behavior Research Foundation (D.A.P.).

Author information

Authors and Affiliations

Authors

Contributions

D.A.P. conceived of and supervised the project. S.C. and C.N.C. designed, performed, and analyzed all experiments, except physiology experiments, which were designed, performed and analyzed by K.L.M. and J.R.F. All authors collaborated to write the manuscript.

Corresponding author

Correspondence to David A Prober.

Ethics declarations

Competing interests

The authors declare no competing financial interests.

Integrated supplementary information

Supplementary Figure 1 Csn induces locomotor activity in embryos expressing TRPV1 in sensory neurons.

(a,b) A representative 24 h.p.f. Tg(islet1:GAL4VP16,4xUAS:TRPV1–RFPT) embryo (lateral view, rostral at left) expresses trpv1–rfpt (magenta) in trigeminal and Rohon–Beard sensory neurons (marked by islet1, green). The boxed region in (a) is shown at higher magnification in (b). Arrows indicate Rohon–Beard neurons that express both trpv1–rfpt and islet1. trpv1–rfpt expression is restricted to islet1–expressing Rohon–Beard neurons, but is only expressed in a subset of these neurons (17/40 islet1–expressing Rohon–Beard neurons express trpv1–rfpt, 3 embryos quantified). Scale bars, 100 μm (a) and 25 μm (b). (c–e) At 2 d.p.f., transgenic embryos (bold colors), but not their WT siblings (faint colors), exhibited a significant increase in locomotor activity (c,d) and in the number of movement bouts (e) in response to 1–10 μM Csn that lasted for up to 2 hours. Mean (c) and mean ± s.e.m. (d,e) are shown. **P<0.01 for transgenic embryos compared to their WT siblings by the Kruskal–Wallis test followed by the Steel–Dwass test to correct for multiple comparisons. 20 embryos were tested for each condition.

Supplementary Figure 2 Increased temperatures induce locomotor activity and neuronal activity in embryos expressing TRPA1 in sensory neurons.

A representative 24 h.p.f. Tg(islet1:GAL4VP16,4xUAS:TRPA1–RFPT) embryo exhibits RFPT fluorescence in trigeminal (arrowhead) and Rohon–Beard sensory neurons (a), as confirmed by trpa1–rfpt (magenta) and islet1 (green) double FISH (b). The boxed region in (b) is shown at higher magnification in (c). Arrows indicate Rohon–Beard neurons that express both trpa1–rfpt and islet1. (28/45 islet1–expressing Rohon–Beard neurons express trpa1–rfpt, 3 embryos quantified). This transgenic line also expresses trpa1–rfpt in some spinal cord interneurons (magenta cells without arrows in [c]). To test the ability of TRPA1 to activate zebrafish sensory neurons, we raised embryos expressing the channel in sensory neurons at or below 26.5oC because the channel is activated at and above 28oC. (d–f) Embryos were raised at 26.5oC and tested at 30 h.p.f., at which time they were developmentally similar to 24 h.p.f. embryos raised at 28.5oC. Embryos were acclimated in E3 medium at 22oC several hours before behavioral assays. Slowly raising the temperature using a heating block (approximately 1oC increase/minute) from 22.5oC to 28.5oC failed to produce a robust locomotor response (data not shown). In contrast, when the temperature was rapidly increased by transferring embryos from E3 medium at 22.5oC to E3 medium pre–heated at specific warmer temperatures, locomotor activity was induced by 1oC to 5oC temperature changes (d), consisting of intense locomotor activity lasting up to 15 seconds (e) with a response latency of 0–5 seconds (f). Rapidly increasing the temperature from 25oC to 28oC produced similar results (data not shown). Temperature increases up to 30oC failed to elicit behavioral responses in WT siblings (Supplementary Video 3 and data not shown), consistent with previous observations. The intense TRPA1–dependent behavioral response could be induced again in 95% of TRPA1–expressing embryos after returning them to 22oC for as little as 2 minutes. (g–i) Embryos were raised at 22.5oC and tested at 3 d.p.f., at which time they were developmentally similar to 2 d.p.f. embryos raised at 28.5oC, and acclimated in E3 medium at 25.5oC for several hours. Transgenic embryos (red), but not their WT siblings (blue), exhibited an increase in locomotor activity (g,h) and in the number of movement bouts (i) following a change in the water temperature from 25.5oC to 28.5oC (approximately 1 minute ramp time) that lasted for up to 2 hours. Arrow in (g) indicates the time of temperature change. Mean (g) and mean ± s.e.m. (e,f,h,i) are shown. *P<0.05 and **P<0.01 for transgenic embryos compared to their WT siblings by the Wilcoxon rank–sum test. (j–l) Representative images showing that c–fos expression is induced in trpa1–rfpt–expressing Rohon–Beard neurons in transgenic embryos after a change in water temperature from 25oC to 28oC (k), but not in non–transgenic siblings subjected to the temperature change (l) or in transgenic siblings maintained at 25oC (j). Animals were fixed 45 minutes after the temperature change. (m) Mean ± s.e.m. percentage of trpa1–rfpt–expressing Rohon–Beard neurons that express c–fos following a 25oC to 28oC temperature change. n indicates the number of embryos analyzed. At least 11 neurons were analyzed per animal in (m). Scale bars, 100 μm (a,b) and 25 μm (c,j–l).

Supplementary Figure 3 Menthol induces locomotor activity and neuronal activity in embryos expressing TRPM8 in sensory neurons.

A representative 24 h.p.f. WT embryo injected with a plasmid containing the islet1:GAL4VP16,4xUAS:TRPM8–RFPT transgene exhibits TRPM8–RFPT fluorescence in a subset of sensory neurons (a), as confirmed by trpm8–rfpt (magenta) and islet1 (green) double FISH (b). The boxed region in (b) is shown at higher magnification in (c). Arrows indicate Rohon–Beard neurons that express both trpm8–rfpt and islet1. (d–f) At 24 h.p.f., transgenic embryos exhibited a dose–dependent locomotor response to menthol, responding to as little as 30 μM (d), with intense locomotor activity lasting up to 9 seconds (e) and a response latency of 0–8 seconds (f). WT embryos did not respond to menthol at any of the concentrations tested (Supplementary Video 4 and data not shown). The behavioral response to menthol could be repeatedly induced in 90% of embryos following drug washout for 2 minutes. Mean (d) and mean ± s.e.m. (e,f) are shown. (g–i) Representative images showing that c–fos expression is induced in trpm8–rfpt–expressing Rohon–Beard neurons in embryos exposed to 100 μM menthol for 45 minutes (h), but not in trpm8–rfpt–expressing Rohon–Beard neurons exposed to the vehicle control (g) or WT neurons exposed to 100 μM menthol (i). Arrows and arrowheads indicate Rohon–Beard sensory neurons that do and do not express c–fos, respectively. islet1 expression was used to identify Rohon–Beard neurons in WT neurons (i). (j) Mean ± s.e.m. percentage of trpm8–rfpt–expressing Rohon–Beard neurons that express c–fos following exposure to 100 μM menthol. n indicates number of embryos analyzed. Average number of neurons analyzed per embryo in (j): TRPM8+ vehicle = 3.3, TRPM8+ 100 μM menthol = 5.2, TRPM8 100 μM menthol = 8.7. Scale bars, 100 μm (a,b) and 25 μm (c,g–i).

Supplementary Figure 4 Csn induces neuronal activity in embryos expressing TRPV1 in sensory neurons.

(a–e) Representative images showing TRPV1–RFPT+ neurons (a–e) and GCaMP5G fluorescence before (a’–e’) and after (a”–e”) addition of Csn. White arrows indicate neurons whose ΔF/Fo values are shown in panels (a”’–e”’). Black arrows (a”’–e”’) indicate Csn addition (t = 0 s) after 10 s of baseline recording. Rohon–Beard neurons were identified in WT embryos by their morphology and location using basal GCaMP5G fluorescence (e). (f) Percentage of TRPV1–RFPT+ Rohon–Beard neurons that showed at least a 50% increase in GCaMP5G fluorescence following exposure to Csn. (g) Average number of calcium transients with at least a 50% increase in ΔF/Fo, per min during 440 s of imaging. Lower values were observed for 10 μM Csn because many neurons exhibited prolonged calcium responses. (h) Average peak ΔF/Fo value of all calcium transients. (i) Average ΔF/Fo during the entire Csn application period. (j) Prolonged calcium response was defined as a calcium transient lasting more than 60 s. Panels (g–i) show mean ± s.e.m. for neurons that respond to Csn. *P<0.05 and **P<0.01 by the Kruskal–Wallis test followed by the Steel–Dwass test to correct for multiple comparisons. n indicates number of embryos (f) or neurons (g–j) analyzed. At least 7 cells were analyzed per embryo in (f). Scale bars, 25 μm.

Supplementary Figure 5 Csn can reversibly and repeatedly stimulate TRPV1–expressing Rohon–Beard sensory neurons.

(a) Images showing TRPV1–RFPT expressing Rohon–Beard neurons and GCaMP5G fluorescence before addition of Csn in a representative Tg(elavl3:GCaMP5G);Tg(hcrt:TRPV1–RFPT) embryo. (b) Change in fluorescence (ΔF/Fo) is plotted for each cell in the field of view for both the first (1–12) and second (1–12) round of 1 μM Csn application, with an intervening 15 minute washout of Csn. (c–e) In each trial, Csn was added after 10 s of baseline recording. For 3 embryos tested, 13 neurons responded to 1 μM Csn, and 10 of these neurons responded to a second exposure to 1 μM Csn (77%). A response was defined as at least a 50% increase in ΔF/Fo. Average number of calcium transients/min during 290 s of imaging (c), average peak ΔF/Fo value for all calcium transients (d) and average ΔF/Fo during the entire Csn application period (e) are quantified for these 10 neurons. Error bars indicate s.e.m.. Scale bar, 50 μm.

Supplementary Figure 6 Csn exposure changes the excitability of TRPV1–expressing Rohon–Beard neurons in exposed spinal cord.

(a) Schematic of experimental setup and representative images from a recorded neuron (inset). Whole–cell patch–clamp recordings were made from TRPV1–RFPT+ neurons in the exposed dorsal spinal cord of Tg(islet1:Gal4VP16,4xUAS:TRPV1–RFPT) embryos at 2 d.p.f. Cells were filled with Alexa Fluor 488 hydrazide (AF488) during recordings and imaged afterward (DIC and fluorescence; white arrowhead indicates a TRPV1+ Rohon–Beard neuron filled with AF488 during recording). Csn was applied by diffusion (b) or perfusion (c) at the side of the recording dish. D, dorsal. V, ventral. nc, notochord. (b) Representative trace from a single TRPV1+ Rohon–Beard cell exposed to Csn by diffusion of a small volume (10 μL) of 100 mM solution from the edge of the dish (100 μM final concentration). For all recorded cells (n=7), after a variable diffusion delay, membrane potential began to depolarize. A stimulus that elicited an action potential before the depolarization ramp (red) was unable to elicit an action potential after the ramp (blue). (c) Responses of a single TRPV1+ Rohon–Beard cell to current injections (–25 and +25–400 pA, 200 ms each, 2 s inter–stimulus interval) during perfusion with 100 μM Csn. Responses to a single stimulus train are overlaid. Early in exposure, the cell’s steady–state membrane potential has not begun to depolarize (pre–ramp), and only single action potentials are evoked by supra–threshold stimuli. As the membrane potential begins to depolarize (mid–ramp), multiple action potentials can be elicited by a single stimulus pulse. Once the membrane potential depolarizes even further (post–ramp), the same stimuli fail to drive a single action potential. Inset scale bars, 5 ms.

Supplementary Figure 7 Perfusion of Csn during whole–cell recording from intact embryos is associated with modest Rohon–Beard cell body depolarization but significantly higher average firing rates compared to DMSO vehicle alone.

(a) Mean number of spikes fired per minute (calculated for the entire recording period for each condition) before, during and after perfusion of 10 μM Csn (magenta lines) or DMSO vehicle alone (black lines). Mean firing rates were significantly higher during perfusion with Csn (P = 0.0119 by Wilcoxon rank–sum test). (b) Resting membrane potential of neurons before, during, and after perfusion of either 10 μM Csn (magenta lines) or DMSO vehicle alone (black lines).

Supplementary Figure 8 Csn induces apoptosis in TRPV1–expressing cells exposed to high Csn levels but does not ablate sensory neurons that do not express TRPV1.

(a–d) Representative images showing that TUNEL labeling was only observed in TRPV1+ neurons exposed to 10 µM Csn. Starting at 24 h.p.f., larvae were exposed to Csn for 6 hours and then processed for TUNEL staining. (e) Mean ± s.e.m. percentage of TRPV1+ Rohon–Beard neurons that are TUNEL positive in a 340 µm region of spinal cord that typically contained ~10 Rohon–Beard neurons. Seven embryos were analyzed for each condition. (f,g) Representative images of Et(e1b:GAL4VP16)s1102t;Tg(14xUAS:EGFP-Aequorin) embryos incubated in vehicle control or 10 μM Csn starting at 28 h.p.f. EGFP fluorescence is unaffected by Csn treatment. (h) Mean ± s.e.m. EGFP fluorescence intensity for the conditions shown in (f,g). Three embryos were analyzed for each condition. The yellow boxes in (f–f”) indicate the regions of interest used to quantify fluorescence at each time point. Scale bars, 50 μm (a–d) and 100 μm (f,g).

Supplementary Figure 9 TRPV1–mediated activation and ablation of Hcrt neurons affects sleep–wake behaviors.

(a) A representative example of Tg(hcrt:TRPV1–RFPT) and Tg(hcrt:EGFP) co–expression in a 5 d.p.f. larva detected using anti–EGFP (green) and anti–RFPT (magenta) IHC. Images show a maximum intensity projection of a 50 μm confocal z–stack. Scale bars, 20 μm. (b) RFPT–positive and EGFP–positive cell counts in Tg(hcrt:TRPV1–RFPT);Tg(hcrt:EGFP) larvae (n = 8) and control Tg(hcrt:EGFP) larvae (n = 2). TRPV1–RFPT was expressed in 85% of EGFP–positive Hcrt neurons, and EGFP was expressed in 95% of TRPV1–RFPT–positive neurons. Thus, the Tg(hcrt:TRPV1–RFPT) line shows specific and nearly comprehensive expression of the transgene in Hcrt neurons. (c,d) Behavioral phenotypes during activation of Hcrt neurons with 1 μM Csn in Tg(hcrt:TRPV1–RFPT) larvae (n = 44) compared to their WT siblings (n = 44). (e,f) Behavioral phenotypes following ablation of Hcrt neurons with 10 μM Csn in Tg(hcrt:TRPV1–RFPT) larvae (n = 52) compared to their WT siblings (n = 43). Box plots indicate median (solid black line), 25th and 75th percentiles (box) and data range (whiskers). *P<0.05, **P<0.01, ***P<0.001 for transgenic larvae compared to their WT siblings by the Wilcoxon rank–sum test. (g,h) Representative images of QRFP neurons detected by anti–EGFP IHC (green), and c–fos expression detected by FISH (magenta), in Tg(hcrt:TRPV1–RFPT) larval brains after incubation 10 μM Csn for 20 minutes. Sagittal images of a 3 d.p.f. larval brain (g, scale bar, 100 μm) and a higher magnification view of the boxed area (h, scale bar, 20 μm) are oriented with rostral at left. Images are maximum intensity projections of 40 µm confocal z–stacks. A gamma correction was uniformly applied across all images to visualize cells with lower signal.

Supplementary Figure 10 Csn does not affect WT larval zebrafish behavior.

Locomotor activity (a,b) and sleep (c,d) of WT larvae treated with DMSO vehicle control (black, n = 40) or 10 μM Csn (magenta, n = 40) are shown. Line plots indicate mean ± s.e.m. Box plots indicate median (solid black line), 25th and 75th percentiles (box) and data range (whiskers). There is no significant difference between vehicle and Csn–treated larvae during any day or night period (p>0.05) by Wilcoxon rank–sum test.

Supplementary information

Supplementary Text and Figures

Supplementary Figures 1–10 and Supplementary Discussion (PDF 2081 kb)

Behavioral response to Csn activation of TRPV1–expressing sensory neurons at 24 hpf.

A Tg(islet1:GAL4VP16,UAS:TRPV1–RFPT) embryo, but not its non–transgenic sibling, exhibits a robust behavioral response when immersed in 1 μM Csn. (MP4 3495 kb)

Behavioral response to Csn activation of TRPV1–expressing sensory neurons at 48 hpf.

Tg(islet1:GAL4VP16,UAS:TRPV1–RFPT) and non–transgenic embryos were placed in alternating wells of a 96–well square–well plate. "+" and "–" indicate transgenic and non–transgenic embryos, respectively. The video begins 20 seconds after addition of DMSO vehicle control (black) or Csn at final concentrations of 0.3 μM (blue) or 3 μM (green). Most embryos treated with 3 μM Csn exhibit bursts of locomotor activity, while embryos treated with vehicle or 0.3 μM Csn exhibit little or no locomotor activity. Note that older embryos are slightly less sensitive to Csn, since 0.3 μM Csn is sufficient to induce a behavioral response at 24 hpf (Fig. 1b–d) but not at 48 hpf. (MP4 700 kb)

Behavioral response to thermal activation of TRPA1–expressing sensory neurons at 24 hpf.

A Tg(islet1:GAL4VP16,UAS:TRPA1–RFPT) embryo, but not its non–transgenic sibling, exhibits a robust behavioral response when transferred from E3 medium at 22.5°C to 27.5°C. (MP4 1040 kb)

Behavioral response to menthol activation of TRPM8–expressing sensory neurons at 24 hpf.

A WT embryo injected with the islet1:GAL4VP16,UAS:TRPM8–RFPT transgene, but not its uninjected sibling, exhibits a robust behavioral response when immersed in 100 μM menthol. (MP4 1691 kb)

Supplementary Data

Plasmid sequence files (ZIP 198 kb)

Rights and permissions

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Chen, S., Chiu, C., McArthur, K. et al. TRP channel mediated neuronal activation and ablation in freely behaving zebrafish. Nat Methods 13, 147–150 (2016). https://doi.org/10.1038/nmeth.3691

Download citation

  • Received:

  • Accepted:

  • Published:

  • Issue Date:

  • DOI: https://doi.org/10.1038/nmeth.3691

Search

Quick links

Nature Briefing

Sign up for the Nature Briefing newsletter — what matters in science, free to your inbox daily.

Get the most important science stories of the day, free in your inbox. Sign up for Nature Briefing