The phase regulation of Ca<sup>2+</sup>-cAMP oscillation and corresponding mathematical modeling.

The phase regulation of Ca<sup>2+</sup>-cAMP oscillation and corresponding mathematical modeling.

<p>(A) Schematic showing out-of-phase Ca<sup>2+</sup>-cAMP oscillation outside the nanodomain and in-phase behavior when localized to AKAP/AC nanodomains. This schematic is designed based on experiments in [<a href="http://www.ploscompbiol.org/article/info:doi/10.1371/journ...

وصف كامل

محفوظ في:
التفاصيل البيبلوغرافية
المؤلف الرئيسي: Lingxia Qiao (19996756) (author)
مؤلفون آخرون: Michael Getz (17692612) (author), Ben Gross (2993145) (author), Brian Tenner (138904) (author), Jin Zhang (53297) (author), Padmini Rangamani (4740435) (author)
منشور في: 2024
الموضوعات:
Biophysics
Biochemistry
Microbiology
Cell Biology
Genetics
Neuroscience
Physiology
Immunology
Cancer
Science Policy
Biological Sciences not elsewhere classified
previous experimental studies
key circuit motif
incoherent feedforward loop
develop computational models
adenylyl cyclase 8
two important predictions
many cellular functions
arbitrary phase difference
div >< p
camp peak simultaneously
2 +</ sup
ac nanodomain formation
phase oscillations associated
enzymes associated
two nanodomains
ac nanodomains
volume ratio
turing pattern
time delay
spatiotemporal orchestration
spatial compartmentation
signaling molecules
second messengers
nanoscale organization
low level
governs camp
give rise
findings unveil
ensuring compartmentation
compartment size
cellular surface
camp oscillations
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الوصف
الملخص:<p>(A) Schematic showing out-of-phase Ca<sup>2+</sup>-cAMP oscillation outside the nanodomain and in-phase behavior when localized to AKAP/AC nanodomains. This schematic is designed based on experiments in [<a href="http://www.ploscompbiol.org/article/info:doi/10.1371/journal.pcbi.1012564#pcbi.1012564.ref032" target="_blank">32</a>] (created with BioRender.com). (B) In this work, we aim to explore the biochemical mechanism of the phase difference (or time delay) between Ca<sup>2+</sup> and cAMP oscillation and study the possible contributing factors. (C) Mathematical modeling of the AKAP-Ca<sup>2+</sup>-cAMP circuit. On the left-hand side, the diagram of the signaling pathway is shown; the solid arrow indicates production, degradation, or binding events, and the dashed arrow indicates the regulation effect that usually does not consume the reactants. The voltage module (highlighted in gray) includes a capacitor with the membrane capacitance <i>C</i><sub><i>m</i></sub> and four ion channels: Ca<sup>2+</sup> channel, K<sup>+</sup> channel, Ca<sup>2+</sup> gated K<sup>+</sup> channel, and leak channel. Currents for ion channels are represented by <i>I</i><sub><i>Ca</i></sub>, <i>I</i><sub><i>K</i></sub>, <i>I</i><sub><i>KCa</i></sub>, and <i>I</i><sub><i>L</i></sub>, where the subscript indicates the specific ion channel. On the right-hand side, the simulation domain is a hexagonal prism, which is only a small compartment of one cell (created with BioRender.com). In this compartment, the top surface (yellow area) denotes the cell membrane; the AKAP/AC nanodomain (the large patch in red) is located on the cell membrane; the volume under the top surface is cytosol. Molecules (dots in gray and orange) can diffuse in the cytosol or on the membrane depending on the location of the molecule. (D) A single AKAP/AC nanodomain was modeled using a Gaussian distribution. (E) Interactions between AC and AKAP that can generate a Turing pattern.</p>

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