Optogenetic Stimulation of Type I GAD65<sup>+</sup>Cells in Taste Buds Activates Gustatory Neurons and Drives Appetitive Licking Behavior in Sodium-Depleted Mice

Baumer-Harrison, Caitlin; Raymond, Martin A.; Myers, Thomas A.; Sussman, Kolbe M.; Rynberg, Spencer T.; Ugartechea, Amanda P.; Lauterbach, Dean; Mast, Thomas G.; Breza, Joseph M.

doi:10.1523/jneurosci.0597-20.2020

Cited by 23 publications

(25 citation statements)

References 66 publications

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“…Type I cells resemble glia and are the most abundant cells present in taste buds. However, the specific function of type I cells remains elusive 17 , 18 . Some researchers regard type I cells as salt detector 4 .…”

Section: Introductionmentioning

confidence: 99%

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

et al. 2022

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The dorsal lingual epithelium, which is composed of taste buds and keratinocytes differentiated from K14+ basal cells, discriminates taste compounds and maintains the epithelial barrier. N6-methyladenosine (m6A) is the most abundant mRNA modification in eukaryotic cells. How METTL3-mediated m6A modification regulates K14+ basal cell fate during dorsal lingual epithelium formation and regeneration remains unclear. Here we show knockout of Mettl3 in K14+ cells reduced the taste buds and enhanced keratinocytes. Deletion of Mettl3 led to increased basal cell proliferation and decreased cell division in taste buds. Conditional Mettl3 knock-in mice showed little impact on taste buds or keratinization, but displayed increased proliferation of cells around taste buds in a protective manner during post-irradiation recovery. Mechanically, we revealed that the most frequent m6A modifications were enriched in Hippo and Wnt signaling, and specific peaks were observed near the stop codons of Lats1 and FZD7. Our study elucidates that METTL3 is essential for taste bud formation and could promote the quantity recovery of taste bud after radiation.

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Section: Introductionmentioning

confidence: 99%

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

et al. 2022

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“…In a recent study, (Baumer-Harrison et al, 2020) used the same constitutive GAD65Cre mice crossed with floxed ChR2 mice to optogenetically stimulate taste buds. To examine reporter expression in taste buds, they used immunocytochemistry to label Type II (PLCb2) and Type III cells (Car4), and counted cells to determine co-localization with the reporter.…”

Section: Discussionmentioning

confidence: 99%

“…Because they express NTPDase2 for the degradation of ATP released by other cells (Bartel et al, 2006;Vandenbeuch et al, 2013), and because they wrap around Type II and Type III cells (Yang et al, 2020), Type I cells are thought to have a glial-like function, similar to astrocytes in the nervous system. However, several studies have suggested a more complex function of Type I cells including a potential role in amiloride-sensitive salt taste transduction (Vandenbeuch et al, 2008, Baumer-Harrison et al, 2020, release of oxytocin to modulate taste (Sinclair et al, 2010), and release of GABA in response to trigeminal modulation with substance P (Huang and Wu, 2018). In order to examine the potential roles of Type I cells a specific marker is needed to both identify isolated cells for physiology and to manipulate gene expression.…”

Section: Introductionmentioning

confidence: 99%

GAD65Cre drives reporter expression in multiple taste cell types

Larson

Vandenbeuch

Anderson

et al. 2021

Preprint

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In taste buds, Type I cells represent the majority of cells (50-60%) and primarily have a glial-like function in taste buds. However, recent studies suggest that they have additional sensory and signaling functions including amiloride-sensitive salt transduction, oxytocin modulation of taste, and substance P mediated GABA release. Nonetheless, the overall function of Type I cells in transduction and signaling remains unclear, primarily because of the lack of a reliable reporter for this cell type. GAD65 expression is specific to Type I taste cells and GAD65 has been used as a Cre driver to study Type I cells in salt taste transduction. To test the specificity of transgene-driven expression, we crossed GAD65Cre mice with floxed tdTomato and Channelrhodopsin (ChR2) lines and examined the progeny with immunochemistry, chorda tympani recording, and calcium imaging. We report that while many tdTomato+ taste cells express NTPDase2, a specific marker of Type I cells, we see expression of tdTomato in both Gustducin and SNAP25 positive taste cells. We also see ChR2 in cells just outside the fungiform taste buds. Chorda tympani recordings in the GAD65Cre/ChR2 mice show large responses to blue light, larger than any response to standard taste stimuli. Further, several isolated tdTomato positive taste cells responded to KCl depolarization with increases in intracellular calcium, indicating the presence of voltage-gated calcium channels. Taken together, these data suggest that GAD65Cre mice drive expression in multiple taste cell types and thus cannot be considered a reliable reporter of Type I cell function.

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“…Type II and type III cells express taste receptors and respond to tastants, while type I cells mainly have glial-like functions. Type I cells have also been suggested to be involved in salt transduction because they express amiloride-sensitive Na + channels (Baumer-Harrison et al, 2020;Roper & Chaudhari, 2017;Vandenbeuch et al, 2008;Yang et al, 2020) but a recent study demonstrated that amiloride-sensitive salt taste is transmitted to the nervous system by a unique cell type that expresses the ATP release channel CALHM1/3 and voltage -gated Na + channels, neither of which are found in Type I taste cells (Nomura et al, 2020).…”

Section: Introductionmentioning

confidence: 99%

“… 2008 ; Roper & Chaudhari, 2017 ; Baumer‐Harrison et al . 2020 ; Yang et al . 2020 ), but a recent study demonstrated that amiloride‐sensitive salt taste is transmitted to the nervous system by a unique cell type that expresses the ATP release channel CALHM1/3 and voltage‐gated Na + channels, neither of which are found in type I taste cells (Nomura et al .…”

Section: Introductionmentioning

confidence: 99%

Functional expression of TMEM16A in taste bud cells

Guarascio

Gonzalez-Velandia

Hernandez-Clavijo

et al. 2021

The Journal of Physiology

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Taste transduction occurs in taste buds in the tongue epithelium -The Ca 2+ -activated Clchannels TMEM16A and TMEM16B play relevant physiological roles in several sensory systems -Here, we report that TMEM16A, but not TMEM16B, is expressed in the apical part of taste buds -Large Ca 2+ -activated Cl − currents blocked by Ani-9, a selective inhibitor of TMEM16A, are measured in type I, but not in type II or III taste cells -ATP indirectly activates Ca 2+ -activated Clcurrents in type I cells through TMEM16A channels -These results indicate that TMEM16A is functional in type I taste cells and contribute to understanding the largely unknown physiological roles of these cells

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Optogenetic Stimulation of Type I GAD65⁺Cells in Taste Buds Activates Gustatory Neurons and Drives Appetitive Licking Behavior in Sodium-Depleted Mice

Cited by 23 publications

References 66 publications

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

GAD65Cre drives reporter expression in multiple taste cell types

Functional expression of TMEM16A in taste bud cells

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Optogenetic Stimulation of Type I GAD65+Cells in Taste Buds Activates Gustatory Neurons and Drives Appetitive Licking Behavior in Sodium-Depleted Mice

Cited by 23 publications

References 66 publications

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

METTL3-mediated m6A RNA methylation regulates dorsal lingual epithelium homeostasis

GAD65Cre drives reporter expression in multiple taste cell types

Functional expression of TMEM16A in taste bud cells

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Optogenetic Stimulation of Type I GAD65⁺Cells in Taste Buds Activates Gustatory Neurons and Drives Appetitive Licking Behavior in Sodium-Depleted Mice