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Printable Handouts
Navigable Slide Index
- Introduction
- Outline
- Impact of Ca2+ stores on Ca2+ signals
- General concepts: Ca2+ sources and sinks
- Fundamental equation: one store model
- The fundamental equation generalized to an arbitrary number of stores
- 3 models illustrating Ca2+ store properties
- Simple linear one-pool model
- Effect of a store on responses to stimulation
- *Properties of the steady-state and [Ca2+] relaxations
- Qualitative properties of the linear one-pool model: geometrical approach
- At fixed [Ca2+]s, Ji varies with [Ca2+]i as in the one-compartment model without Ca2+ stores
- Nullcline analysis in the [Ca2+]i, [Ca2+]s plane
- Assessing the stability of the steady-state: linear system
- Effects of stimulation
- The new point of intersection of Ji and Js nullclines defines a new steady-state
- An ER store with Ca2+ release channels that mediate CICR
- Responses to stimulation, steady-states and stability
- [Ca2+]i can be induced to oscillate by a steady stimulus
- Critical points during the oscillatory cycle (1)
- Critical points during the oscillatory cycle (2)
- Critical points during the oscillatory cycle: experiment
- Self-sustaining Ca2+ release
- Accounting for temporal properties of [Ca2+]i and the underlying fluxes
- Qualitative properties of the nonlinear system: flux/[Ca2+] relations
- Steady-state(s) analysis at fixed (resting) [Ca2+]s
- Effect of the Ca2+ sensitive release channels on Ji at constant [Ca2+]s near resting [Ca2+]i
- Relationship between [Ca2+]s dynamics and the cytosolic Ca2+ flux at constant [Ca2+]s
- Assessing the stability of the steady-state: nonlinear system (1)
- Assessing the stability of the steady-state: nonlinear system (2)
- The new steady-state is unstable
- The system orbits around the unstable equilibrium
- *Ca2+ oscillations viewed from the perspective of the Ji/ci flux relation
- *Analysis of the Ji/ci flux relations at critical time points
- Recap of modelling Ca2+ stores so far…
- End of Part 2
Topics Covered
- Qualitative properties of Ca2+ dynamics
- Steady states
- The impact of Ca2+ stores on Ca2+ signals
- Ca2+ sources and sinks
- The linear one-pool model
- Nullclines
- Ca2+ induced Ca2+ release (CICR)
- Ca2+ oscillatory cycles
- The nonlinear model
Talk Citation
Friel, D. (2021, August 30). Modeling Ca2+ signals: understanding Ca2+ regulatory networks in cells - Ca2+ stores: endoplasmic reticulum, calcium oscillations [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved October 13, 2024, from https://doi.org/10.69645/OYBP8676.Export Citation (RIS)
Publication History
Financial Disclosures
- Dr. David Friel has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Modeling Ca2+ signals: understanding Ca2+ regulatory networks in cells - Ca2+ stores: endoplasmic reticulum, calcium oscillations
Published on August 30, 2021
41 min
A selection of talks on Cell Biology
Transcript
Please wait while the transcript is being prepared...
0:05
We will next turn to multi-compartmental models and then describe
several biologically relevant examples where
calcium-dependent channel gating has a powerful effect on calcium dynamics.
0:18
Now, that we have outlined the basic approach for describing
calcium dynamics in a cell with a single compartment.
Let's now turn to a discussion of calcium stores.
We will first discuss general concepts,
followed by an analysis of
a simple linear one-pool model that illustrates
many of the basic effects that stores can have on calcium dynamics.
Then we will describe interesting properties imparted to calcium signaling when stores
express calcium channels that open in response
to elevations in the cytosolic calcium concentration.
There are two general cases that differ in terms of
the direction in which calcium flows when these channels open,
which is in turn determined by the driving force on calcium,
as established by the specific transport systems that operate in the respective stores.
In the first case,
which is relevant to the endoplasmic reticulum,
such channels make it possible for a store to support calcium-induced calcium release.
In the second case,
which is relevant to mitochondria,
calcium-sensitive channels permit intracellular calcium uptake
at a rate that is highly sensitive to the cytosolic calcium levels.
Understanding how these stores individually contribute to calcium signaling is critical
for understanding how they work together when operating simultaneously in the same cell.
1:31
Calcium stores are membrane delimited intracellular compartments that use
specific calcium transport and buffering
systems to regulate their intraluminal calcium levels.
Examples include the endoplasmic reticulum, mitochondria,
the nucleus, as well as other organelles such as
the Golgi apparatus and secretory vesicles.
We now have the basic conceptual tools for grappling
with the effects of such stores on calcium dynamics.
At a given instant in time,
the impact of a store on the intracellular distribution of
calcium depends on the net calcium flux between the store and the cytosol,
which we call the inter-compartmental calcium flux, Js.
This flux can mediate either a loss or gain of store calcium,
in which case the store would be described as a source or sink respectively.
In the same way that the interdepartmental calcium flux across
the plasma membrane depends on
the relative rates of transport via different transport systems.
The direction and magnitude of Js depends on the relative rates of
transport via pathways that mediate calcium uptake and release.
Among the interesting features of calcium signaling stores are the following.
First, net calcium uptake and release by
a store affects cytosolic and intraluminal calcium levels interdependently,
for example, net calcium release from a store which reduces intraluminal calcium levels,
must also increase cytosolic calcium levels.
Secondly, if stores act as sinks or sources during stimulation,
they tend to act as sources or sinks after the stimulus
ends as is pre-stimulus calcium distribution is restored.
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