Interrogating cyclic AMP signaling using optical approaches

Jiang, Jason; Falcone, Jeffrey L.; Curci, Silvana; Hofer, Aldebaran M.

doi:10.1016/j.ceca.2017.02.010

Cited by 26 publications

(26 citation statements)

References 75 publications

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“…This timeline gives an overview of the cAMP and Ca 2+ methodological progresses from discovery to present including some representative references. Data for timeline as reported in literature (for detailed cAMP reporters see Jiang, Falcone, Curci, and Hofer (); Musheshe, Schmidt, and Zaccolo (); Paramonov, Mamaeva, Sahlgren, and Rivero‐Muller (); Schleicher and Zaccolo ()) (for Ca2+ see Campbell (); Grienberger and Konnerth (); Looger and Griesbeck (); Suzuki, Kanemaru, and Iino ()). ∧ , Salomon, Londos, and Rodbell (); Г , Takeda, Kuno, Shuntoh, and Tanaka (); ᶳ, Nordstedt and Fredholm (); °, Adams, Harootunian, Buechler, Taylor, and Tsien (); ¤ , Zaccolo et al (); Zaccolo and Pozzan (); ¥ , DiPilato et al (); Nikolaev, Bunemann, Hein, Hannawacker, and Lohse (); Ponsioen et al (); ₽ , Nikolaev et al ()ᶤ, Everett and Cooper (); + , Sprenger et al (); £ , Vergara and Delay (); *, Grynkiewicz, Poenie, and Tsien (); ҍ , Tsien, Rink, and Poenie (); ᶬ, Kendall, Sala‐Newby, Ghalaut, Dormer, and Campbell (); ᶣ, Romoser, Hinkle, and Persechini (); ᶲ, Miyawaki et al (); ᶿ, Nakai, Ohkura, and Imoto (); Sawano and Miyawaki (); Ω , Wang, Wong, Flores, Vosshall, and Axel (); Ⅎ , Ji et al (); ⋔ , Tallini et al (); ℓ , Willoughby, Wachten, Masada, and Cooper (); †, Dana et al ().…”

Section: Methods To Study Camp Signaling Dynamicsmentioning

confidence: 99%

“…This timeline gives an overview of the cAMP and Ca 2+ methodological progresses from discovery to present including some representative references. Data for timeline as reported in literature (for detailed cAMP reporters see Jiang, Falcone, Curci, and Hofer (2017) Everett and Cooper (2013); + , Sprenger et al (2015); £ , Vergara and Delay (1985); *, Grynkiewicz, Poenie, and Tsien (1985); ҍ , Tsien, Rink, and Poenie (1985); ᶬ, Kendall, Sala-Newby, Ghalaut, Dormer, and Campbell (1992); ᶣ, Romoser, Hinkle, and Persechini (1997); ᶲ, Miyawaki et al (1997); ᶿ, Nakai, Ohkura, and Imoto (2001); Sawano and Miyawaki (2000); Ω , Wang, Wong, Flores, Vosshall, and Axel (2010); †, Dana et al (2018). Abbreviations: AC, adenylyl cyclase; Epac, exchange protein directly activated by cAMP; GECI, genetically encoded Ca 2+ indicators; HCN2, hyperpolarizationactivated cyclic nucleotide-gated channel 2; PEI, polyethyleneimine; PKA, protein kinase A; PLN, phospholamban; PM, plasma membrane; smGC, smooth muscle isoform of myosin heavy chain-GCaMP1 expressing mice expressing a targeted cAMP biosensor have been produced and successfully employed to study a cAMP microdomain in proximity to SERCA pumps in cardiac myocytes (Sprenger et al, 2015).…”

Section: Methods To Study Camp Signaling Dynamicsmentioning

confidence: 99%

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Aspects of astrocytic cAMP signaling with an emphasis on the putative power of compartmentalized signals in health and disease

Reuschlein

Jakobsen

Mertz

et al. 2019

Glia

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This review discusses aspects of known and putative compartmentalized 3′,5′‐cyclic adenosine monophosphate (cAMP) signaling in astrocytes, a cell type that has turned out to be a key player in brain physiology and pathology. cAMP has attracted less attention than Ca2+ in recent years, but could turn out to rival Ca2+ in its potential to drive cellular functions and responses to intra— and extracellular cues. Further, Ca2+ and cAMP are known to engage in extensive crosstalk and cAMP signals often take place within subcellular compartments revolving around multi‐protein signaling complexes; however, we know surprisingly little about this in astrocytes. Here, we review aspects of astrocytic cAMP signaling, provide arguments for an increased interest in this subject, suggest possible future research directions within the field, and discuss putative drug targets.

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Section: Methods To Study Camp Signaling Dynamicsmentioning

confidence: 99%

“…This timeline gives an overview of the cAMP and Ca 2+ methodological progresses from discovery to present including some representative references. Data for timeline as reported in literature (for detailed cAMP reporters see Jiang, Falcone, Curci, and Hofer (2017) Everett and Cooper (2013); + , Sprenger et al (2015); £ , Vergara and Delay (1985); *, Grynkiewicz, Poenie, and Tsien (1985); ҍ , Tsien, Rink, and Poenie (1985); ᶬ, Kendall, Sala-Newby, Ghalaut, Dormer, and Campbell (1992); ᶣ, Romoser, Hinkle, and Persechini (1997); ᶲ, Miyawaki et al (1997); ᶿ, Nakai, Ohkura, and Imoto (2001); Sawano and Miyawaki (2000); Ω , Wang, Wong, Flores, Vosshall, and Axel (2010); †, Dana et al (2018). Abbreviations: AC, adenylyl cyclase; Epac, exchange protein directly activated by cAMP; GECI, genetically encoded Ca 2+ indicators; HCN2, hyperpolarizationactivated cyclic nucleotide-gated channel 2; PEI, polyethyleneimine; PKA, protein kinase A; PLN, phospholamban; PM, plasma membrane; smGC, smooth muscle isoform of myosin heavy chain-GCaMP1 expressing mice expressing a targeted cAMP biosensor have been produced and successfully employed to study a cAMP microdomain in proximity to SERCA pumps in cardiac myocytes (Sprenger et al, 2015).…”

Section: Methods To Study Camp Signaling Dynamicsmentioning

confidence: 99%

Aspects of astrocytic cAMP signaling with an emphasis on the putative power of compartmentalized signals in health and disease

Reuschlein

Jakobsen

Mertz

et al. 2019

Glia

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“…Different PDEs mediate the breakdown of cAMP by hydrolyzing it to AMP [31]. Using visualization technologies, the existence of cell-and context-specific cAMP nanodomains has been demonstrated [32][33][34][35][36][37][38][39][40]. Spatially separated pools of cAMP are likely to be engaged in different functional outputs.…”

Section: Camp Mobilizationmentioning

confidence: 99%

Hedgehog and Gpr161: Regulating cAMP Signaling in the Primary Cilium

Tschaikner

Enzler

Torres‐Quesada

et al. 2020

Cells

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Compartmentalization of diverse types of signaling molecules contributes to the precise coordination of signal propagation. The primary cilium fulfills this function by acting as a spatiotemporally confined sensory signaling platform. For the integrity of ciliary signaling, it is mandatory that the ciliary signaling pathways are constantly attuned by alterations in both oscillating small molecules and the presence or absence of their sensor/effector proteins. In this context, ciliary G protein-coupled receptor (GPCR) pathways participate in coordinating the mobilization of the diffusible second messenger molecule 3′,5′-cyclic adenosine monophosphate (cAMP). cAMP fluxes in the cilium are primarily sensed by protein kinase A (PKA) complexes, which are essential for the basal repression of Hedgehog (Hh) signaling. Here, we describe the dynamic properties of underlying signaling circuits, as well as strategies for second messenger compartmentalization. As an example, we summarize how receptor-guided cAMP-effector pathways control the off state of Hh signaling. We discuss the evidence that a macromolecular, ciliary-localized signaling complex, composed of the orphan GPCR Gpr161 and type I PKA holoenzymes, is involved in antagonizing Hh functions. Finally, we outline how ciliary cAMP-linked receptor pathways and cAMP-sensing signalosomes may become targets for more efficient combinatory therapy approaches to counteract dysregulation of Hh signaling.

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“…The first genetically encoded cAMP sensor was generated tagging the PKA with two FRET-suited GFP mutants and this was used to monitor cAMP fluctuation in cardiac myocytes [252,253]. Since then, cAMP sensors have been continuously improved including newly discovered cAMP binding sequences and fluorescent proteins (for reviewed see [254]). Furthermore, subcellular targeting of such sensors permits to study changes in cAMP levels in microand nanodomains [255] and the genetic approach renders them suitable for studies in recombinant cells lines, primary cells and in vivo [256][257][258].…”

Section: Camp Sensorsmentioning

confidence: 99%

Sensing Senses: Optical Biosensors to Study Gustation

Molitor

Riedel

Hafner

et al. 2020

Sensors

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The five basic taste modalities, sweet, bitter, umami, salty and sour induce changes of Ca2+ levels, pH and/or membrane potential in taste cells of the tongue and/or in neurons that convey and decode gustatory signals to the brain. Optical biosensors, which can be either synthetic dyes or genetically encoded proteins whose fluorescence spectra depend on levels of Ca2+, pH or membrane potential, have been used in primary cells/tissues or in recombinant systems to study taste-related intra- and intercellular signaling mechanisms or to discover new ligands. Taste-evoked responses were measured by microscopy achieving high spatial and temporal resolution, while plate readers were employed for higher throughput screening. Here, these approaches making use of fluorescent optical biosensors to investigate specific taste-related questions or to screen new agonists/antagonists for the different taste modalities were reviewed systematically. Furthermore, in the context of recent developments in genetically encoded sensors, 3D cultures and imaging technologies, we propose new feasible approaches for studying taste physiology and for compound screening.

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Interrogating cyclic AMP signaling using optical approaches

Cited by 26 publications

References 75 publications

Aspects of astrocytic cAMP signaling with an emphasis on the putative power of compartmentalized signals in health and disease

Aspects of astrocytic cAMP signaling with an emphasis on the putative power of compartmentalized signals in health and disease

Hedgehog and Gpr161: Regulating cAMP Signaling in the Primary Cilium

Sensing Senses: Optical Biosensors to Study Gustation

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