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- Introduction to Calcium Signaling
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1. Introduction to cellular calcium signaling
- Dr. Martin Bootman
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2. Monitoring Ca2+ concentration in living cells
- Dr. Marisa Brini
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3. Cell boundary theorem
- Prof. Eduardo Ríos
- Calcium Influx
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4. Arachidonic acid and store-independent Ca2+ entry
- Dr. Luca Munaron
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5. Voltage-dependent calcium channels
- Prof. Annette Dolphin
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7. Intracellular Ca2+ signaling: calcium influx
- Prof. Anant Parekh
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8. Molecular identification of the CRAC channel
- Prof. Michael Cahalan
- Calcium Release
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10. The InsP3 receptor calcium release channel
- Prof. J. Kevin Foskett
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11. Molecular biology of ryanodine receptors: an overview
- Dr. Christopher George
- Prof. F. Anthony Lai
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12. cADPR and NAADP: messengers for calcium signalling
- Prof. Antony Galione
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13. Ryanodine receptors and cardiac function
- Prof. David Eisner
- Calcium Efflux and Sequestration
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14. Sodium-calcium exchange
- Prof. John Reeves
- Organelle Calcium
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15. Regulation and role of mitochondrial Ca2+ homeostasis
- Prof. Rosario Rizzuto
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16. Peroxisomes and Golgi apparatus as players in Ca2+ homeostasis
- Dr. Paola Pizzo
- Dr. Alex Costa
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17. Ca2+ dynamics between mitochondria and the endoplasmic reticulum
- Dr. Wolfgang Graier
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18. Nuclear calcium signaling
- Dr. Oleg Gerasimenko
- Dr. Julia Gerasimenko
- Spatiotemporal Calcium Signals
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19. Regulation of intracellular calcium signaling, localized signals and oscillations
- Prof. Barbara Ehrlich
- Calcium Effectors
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24. Calcium-regulated adenylyl cyclases and cyclic AMP compartmentalization
- Prof. Dermot Cooper
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25. Calcium and transcription-coupling
- Dr. Karen Lounsbury
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26. Cellular calcium (Ca2+) buffers
- Prof. Dr. Beat Schwaller
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27. Extracellular calcium signaling
- Dr. Aldebaran M. Hofer
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28. Ca2+, fertilization and egg activation
- Prof. Karl Swann
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29. Calcium regulation of transcription in plants
- Prof. Hillel Fromm
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30. Mechanisms regulating STIM expression and function in Ca2+ signaling
- Dr. Jonathan Soboloff
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31. Dynamic signal encoding in the S. cerevisiae calcium response
- Dr. Chiraj Dalal
- Calcium and Disease
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32. Polycystins, calcium signaling and pathogenesis of polycystic kidney disease
- Prof. Laura del Senno
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33. Ca2+ alterations in familial Alzheimer's disease (FAD)
- Dr. Paola Pizzo
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34. Pancreatitis and calcium signaling
- Prof. Ole Petersen
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35. Mechanism-based therapies for heart failure and cardiac arrhythmias
- Prof. Andrew Marks
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36. Genetic defects and calcium
- Prof. Tullio Pozzan
- Archived Lectures *These may not cover the latest advances in the field
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37. Calcium, calmodulin and calcineurin
- Prof. Stephen Bolsover
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38. Calcium flickers steer cell migration
- Prof. Heping Cheng
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39. Automated Ca2+ imaging of chemosensory neurones in C.elegans
- Dr. Nikos Chronis
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40. Ca2+ and the regulation of small GTPases
- Prof. Peter Cullen
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41. Genetically encoded Ca2+ indicators: molecular scale measurements in mammals in vivo
- Dr. Michael I. Kotlikoff
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42. Capacitative (store-operated) calcium entry
- Dr. Jim Putney
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43. The molecular biology of the inositol trisphosphate receptor
- Dr. Randen Patterson
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44. Coordinated Ca2+ release from intracellular Ca2+ stores
- Prof. Ole Petersen
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45. The plasma membrane calcium pump: biochemistry, physiology and molecular pathology
- Prof. Ernesto Carafoli
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46. The calcium saga: a matter of life and death
- Prof. Pierluigi Nicotera
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47. Ca2+ efflux and Ca2+ signals
- Dr. Anne Green
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50. Modeling Ca2+ signals
- Dr. David Friel
Printable Handouts
Navigable Slide Index
- Introduction
- Physiological roles of Ca2+ signals
- Receptor-mediated control of Ca2+ signals
- STIM1 and STIM2 are components of SOCs
- Orai 1 as component of store operated Ca2+ entry
- STIM-Orai coupling details
- Transcriptional mechanisms regulating Ca2+
- The EGR Family of transcription factors
- Wilms tumor suppressor 1 (WT1)
- STIM1 expression is dysregulated in Wilms' tumor
- STIM1 expression is dependent on WT1 and EGR1
- Dysregulation of STIM1 expression in EGR1 KO
- ChIP Analysis of the STIM1 promoter
- Control of STIM1 expression by WT1 and EGR1
- Dynamic EGR1-mediated control of STIM1
- Receptor control of EGR1, STIM1/2, PMCA
- Altered STIM, PMCA expression alters Ca2+
- Inhibition of Ca2+ clearance due to PMCA activity
- STIM1-PMCA role in inhibition of Ca2+ clearance
- Orai1 activation/PMCA inhibition - STIM1 functions
- Polarization of T cells during synapse formation
- STIM1 and PMCA co-localize at the site of PHA
- Identification of the critical STIM1 domain
- STIM1 KD eliminates inhibition of Ca2+ clearance
- Local control of cytosolic Ca2+ content (1)
- Global control of Ca2+ clearance after STIM1 KD
- Local control of cytosolic Ca2+ content (2)
- Remodeling of Ca2+ homeostasis at synapse
- Acknowledgements
Topics Covered
- Basic concepts and physiological implications
- Transcriptional mechanisms in control of STIM1 expression
- Dynamic receptor-mediated STIM1 upregulation
- Delayed Ca2+ clearance during T cell activation
- Role of STIM1 in this process
Links
Series:
Categories:
Therapeutic Areas:
Talk Citation
Soboloff, J. (2020, August 12). Mechanisms regulating STIM expression and function in Ca2+ signaling [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 12, 2024, from https://doi.org/10.69645/PAIP1774.Export Citation (RIS)
Publication History
Financial Disclosures
- Dr. Jonathan Soboloff has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
Mechanisms regulating STIM expression and function in Ca2+ signaling
A selection of talks on Oncology
Transcript
Please wait while the transcript is being prepared...
0:00
Hello my name is Jonathan Soboloff and
today I'm going to talk a little bit
about some recent work performed in
my lab, investigating mechanisms
regulating STIM expression and
function in calcium signaling.
0:14
Before getting too far
into my current research,
I'd like to talk a little about the
physiological roles of calcium signals.
Calcium signals control a wide variety
of distinct physiological events.
Whereas calcium signals themselves
typically occur quite rapidly in a time
frame of seconds to minutes,
the physiological consequences of these
signals can last over
a much longer time period.
Some of the immediate effects of calcium
signals can be detected immediately
over a time frame,
similar to the calcium signal itself.
For example, muscle contraction, changes
in the metabolic state of certain enzymes,
or membrane fusion, such as for
example in secretion.
Other calcium signals occur
over a much longer time frame,
really long after the calcium
signal has already ended,
such as changes in gene expression,
changes in cell proliferation, or
changes in apoptosis (otherwise
known as cell death).
The major goal of my lab is to understand
this link between short-term changes
in calcium signals and these
longer-term changes in cell function.
1:20
Now I'd like to talk a little about
receptor-mediated control of calcium
signals.
At rest, the concentration of
calcium in the cytosol is many-fold
lower than outside of the cell or
in the lumen of the.
This difference is maintained by
the combined action of the plasma
membrane calcium ATPase (PMCA) and
the sarco/endoplasmic reticulum
calcium ATPase (SERCA).
When a ligand binds to a PLC
(phospholipase C-coupled receptor),
it initiates a series of events leading
to elevation of cytosol calcium
concentration.
The first step in this process is
breakdown of phosphatidyl inositol (PIP2)
into two bio-active metabolites,
diacylglycerol (DAG) and IP3.
DAG has a number of different targets,
one of which is receptor-operated calcium
channels (ROCs), which upon binding
of diacylglycerol permit the entry of
calcium into the cytosol from
the extracellular space.
IP3 binds to its receptor on the Membrane,
causing the movement of calcium
out of the Lumen and into the cytoplasm,
and this movement of calcium out
of the Lumen tends to cause
a depletion of Calcium concentration.
This Calcium depletion leads to the
activation of a separate class of calcium
channels, termed store-operated
calcium channels (SOCs).
Because both SOCs and ROCs are activated
downstream of receptors at least
physiologically, there's been a great
deal of confusion over the years over
whether a channel is receptor-operated or
store-operated.
Much of this confusion was
addressed in 2005 and 2006,
with the identification of
the molecular mediators of SOC and
it's these proteins that have been
the focus of my research since that time.