Regulation of the IP 3 Receptor by Ca 2+ and Ca 2+ -binding Proteins.

Slides:

Advertisements

Similar presentations

1 Chapter 24 Calcium Copyright © 2012, American Society for Neurochemistry. Published by Elsevier Inc. All rights reserved.

Advertisements

Calcium Homeostasis and Signaling in Yeast Cells and Cardiac Myocytes Jiangiun Cui, J.A. Kaandorp, P.M.A. Sloot Section Computational Science University.

G Linked Receptors (Continued…….). Serine/Threonine Protein Phosphatases Rapidly Reverse the Effects of A-Kinase.

Cell Communication Chapter 11 Local regulators – in the vicinity a.Paracrine signaling – nearby Cells are acted on by signaling Cell (ie. Growth factor)

Calcium Signals Copyright © by Joyce J. Diwan. All rights reserved. Biochemistry of Metabolism.

Cell Communication (Signaling) Part 2

Cytosolic [Ca] RyR2 open probability ECC gain Ca transient contractility DADs - SCD [Ca] Time Iso CHF.

BIOC DR. TISCHLER LECTURE 22 SIGNAL TRANSDUCTION: G-PROTEINS.

Signal Transduction Pathways

Lecture 05 – Extracellular Signal Receptors III Lecture 05 – Extracellular Signal Receptors III BIOL 5190/6190 Cellular & Molecular Singal Transduction.

Mapping of Calmodulin Binding Sites on the IP 3 R1 N. Nadif Kasri, I. Sienaert, J.B. Parys, G. Callewaert, L. Missiaen and H. De Smedt Laboratory of Physiology,

Copyright © 2005 Pearson Education, Inc. publishing as Benjamin Cummings Chapter 11 Cell Communication.

The four units of the Ca 2+ signalling network Nature Rev. Mol. Cell Biol. 1, (2000) Speed Amplitude Spatio-temporal pattern.

Please turn in your completed case study (all parts!)

Copyright, 1999 © Mark Chambers Endocrine Physiology Dr. Mark Chambers D.V.M., Ph.D.

Calmodulin in action: Diversity in target recognition and Activation Mechanism.

Cytokines, Growth Factors and Hormones SIGMA-ALDRICH.

Calcium-dependent gating of Voltage-gated Ca 2+ channels Regulation by Calmodulin.

University of Jordan1 Receptors Functions and Signal Transduction- L3 Faisal I. Mohammed, MD, PhD.

Modulation de la structure, localisation et fonction des récepteurs pour l’inositol trisphosphate: le rôle des interactions protéiques. Jan B. Parys K.U.Leuven.

Voltage-gated Ca 2+ Channels (VGCCs) For review, see: Catterall, Annu. Rev. Cell Dev. Biol. 16:

Cell Communication.

Signal Transduction Lecture 14. Ligands & Receptors n Ligand l Neurotransmitters & drugs n Receptor proteins l ligand binds to multiple receptors n Binding.

Cell Communication Chapter Cell Communication: An Overview  Cells communicate with one another through Direct channels of communication Specific.

Regulation of the IP3 Receptor by Ca2+ and Ca2+-Binding Proteins

Chapter 11 Cell Communication. Concept Check Questions Chapter 11 Cell Communication.

Chapter 11 Cell Communication. LE 11-2 Exchange of mating factors Mating Receptor a   factor a  a factor Yeast cell, mating type a Yeast cell, mating.

Chapter 14. Signal Transduction Signal transduction is the process by which an extracellular signal alters intracellular events. 1. First and second messengers.

Lecture: Cell Signaling

Intracellular calcium release channels as multi-protein complexes Jan B. Parys K.U.Leuven 7 th ECS meeting, June 13th, 2002.

ms [Ca] i (nM) 10 µm Ca 2+ Signaling Mark T Ziolo, PhD Department of Physiology & Cell Biology 019 Hamilton Hall

AP Biology Cell Communication. AP Biology Communication Methods  Cell-to-cell contact  Local signaling  Long distance signaling.

Mapping of Calmodulin binding sites on the IP3R1 N. Nadif Kasri; I. Sienaert, S. Vanlingen, J.B. Parys, G. Callewaert, L. Missiaen and H. De Smedt Laboratory.

Regulation of intracellular Ca 2+ -release channels by Ca 2+ and Ca 2+ -binding proteins Nael Nadif Kasri September 21st, 2004.

IP 3 -induced Ca 2+ release and calmodulin Laboratory of Physiology KULeuven Leuven, Belgium.

Contraction Mechanism Actin and myosin interact via to the sliding filament mechanism Resting State –Actin bound by caldesmon –Myosin light chain (MLC)

Regulation of the IP 3 Receptor by Ca 2+ and Ca 2+ -binding Proteins.

TARGETS FOR G-PROTEINS The main targets for G-proteins, through which GPCRs control different aspects of cell function are: adenylyl cyclase, the enzyme.

Regulation of inositol 1,4,5- trisphosphate (IP 3 ) receptors and IP 3 -induced Ca 2+ release H. De Smedt K.U.Leuven, Belgium.

Overview: The Cellular Internet Cell-to-cell communication is essential for multicellular organisms Biologists have discovered some universal mechanisms.

IP3-induced Ca2+ release and calmodulin

Chapter 11 Cell Communication.

Cell Communication.

Neuroscience Fundamentals 112C Ian Parker

What does the following have in common?

Translation initiation factor eIF2: Initiation and Recycling

Cell Communication (Signaling) Part 2

Patrick Delmas, Bertrand Coste, Nikita Gamper, Mark S. Shapiro Neuron

Cell Communication (Signaling) Part 2

Intracellular Receptors

Gene expression, LTP, ion channels, enzymes, cell death

Cell Communication.

HFpEF, a Disease of the Vasculature: A Closer Look at the Other Half

Signal Transduction Dr. Nasim.

Nat. Rev. Endocrinol. doi: /nrendo

Volume 131, Issue 6, Pages (December 2007)

Signal transduction and hepatocellular bile acid transport: Cross talk between bile acids and second messengers Bernard Bouscarel, Spencer D. Kroll,

Cell Communication (Signaling) Part 2

Mark S Taylor, A.Marie McMahon, Jason D Gardner, Joseph N Benoit

Calcium Signals Tune the Fidelity of Transcriptional Responses

Heme oxygenase: protective enzyme or portal hypertensive molecule?

Organelle crosstalk in the kidney

Cell Communication (Signaling) Part 2

Signal Transduction Lecture 14. Ligands & Receptors n Ligand l Neurotransmitters & drugs n Receptor proteins l ligand binds to multiple receptors n Binding.

Calcium Release Channels

Neuronal Calcium Signaling

Targeting TNF-α: A novel therapeutic approach for asthma

Vocabulary Match-Fest

Linking Calcium to Aβ and Alzheimer's Disease

Long-distance signaling

Presentation transcript:

Regulation of the IP 3 Receptor by Ca 2+ and Ca 2+ -binding Proteins

Introduction: Calcium signalling Inositol trisphosphate receptor (IP3R) Results: Regulation of the IP3R by Ca2+ and calmodulin Regulation of intracellular Ca2+ release by neuronal Ca2+ binding proteins A novel Ca2+-induced Ca2+ release mechanism in A7r5 and 16HBE014-cells Conclusions Perspectives

Ca2+

VGCC LGCC SOCC (TRP) MSCC PMCA NCX RYR ER/SR SERCA IP 3 R Golgi PMR1 Mitochondria NCX Uniporter Buffers R Second messenger IP 3 R Others??

Introduction: Calcium signalling Inositol trisphosphate receptor (IP3R) Results: Conclusions Perspectives Regulation of the IP3R by Ca2+ and calmodulin Regulation of intracellular Ca2+ release by neuronal Ca2+ binding proteins A novel Ca2+-induced Ca2+ release mechanism in A7r5 and 16HBE014-cells

Introduction IP 3 R Regulation of the IP 3 R by Ca 2+ and CaM Results Localization and characterization of the CaM-binding sites Function of CaM Regulation of the IP 3 R by Neuronal Ca 2+ -binding proteins Conclusions

IP 3 R I, II, III Agonists IP 3 Ca 2+ Intraluminal proteins: Chromogranins; Calnexin, Calreticulin Cytosolic proteins: Calmodulin; CaBP IRBIT; CARP Cytoskeletal proteins: Actin; MyosinII Ankyrin; Talin; Vinculin 4.1N Plasma membrane associated: Homer-mGluR TRPs; G  Kinases and phosphatases: PKA; PKC BANK- PTK IRAG-PKG FKBP12-Calcineurin PP1  ER cytosol

Ca 2+ is the primary modulator of its own release Structure of the IP 3 R Regulation of the IP 3 R by Ca 2+ Bell-shaped IICR Hamada et al., 2002 Bezprozvanny et al., 1991

IICR Regulation of the IP 3 R by CaM + CaM (Missiaen et al., 1999) [Ca 2+ ] (nM)300 - CaM (Michikawa et al., 1999) CaM Ca 2+ dependently inhibits IP 3 R I, II and III IP 3 R I II III

Calmodulin binding sites on IP 3 R1 13 Endoplasmic reticulum Cytosol R1:LDSQVNNLFLKSHN-IVQKTAMNWRLSARN-AARRDSVLA R2:LDSQVNTLFMKNHSSTVQRAAMGWRLSARSGPRFKEALGG R3:LDAHMSALLSSGGSCSAAAQRSAANYKTATRTFPRVIPTA CaCaM CaM (Adkins et al,2000) W1577A (Zhang et al, 2001; Nosyreva et al, 2002)

Localization and characterization of the CaM-binding sites Results

Calmodulin effects on IP 3 binding CaM inhibits IP 3 binding in Ca 2+ -independent way C N B/F Bound (nM) [ 3 H]IP 3 binding (%) Control CaM Ca 2+ /CaM CaM 1234 Ca 2+ /CaM 1234 Ca 2+ IP 3 binding core

Localisation of a calmodulin-binding site GST-fusion protein pull down of CaM 1234 CaM 1234 pGST GST-Cyt1 GST-Cyt2 50  M free Ca 2+ 1 mM EGTA CaM 1234 Cyt1 Cyt IP 3 binding core

Detailed localisation using peptides A B C D E F CaM A B C E D F % IQ 76% IQ 53% IQ A B C D E F CaM Ca 2+ EGTA Discontinue Ca 2+ -independent CaM-binding site in the N- terminal region

A B C E D F 1159 control∆ B∆ E [ 3 H]IP 3 binding Both CaM-binding sites are essential for inhibiting IP 3 binding CaM

Calmodulin-binding sites on IP 3 R1 13 ER Cytosol R1:LDSQVNNLFLKSHN-IVQKTAMNWRLSARN-AARRDSVLA R2:LDSQVNTLFMKNHSSTVQRAAMGWRLSARSGPRFKEALGG R3:LDAHMSALLSSGGSCSAAAQRSAANYKTATRTFPRVIPTA R1:PPKKFRDCLFKLCPMNRYSAQKQFWKAAKPGAN R2:PPKKFRDCLFKVCPMNRYSAQKQYWKAKQAKQG R3:PPKKFRDCLFKVCPMNRYSAQKQYWKAKQTKQD CaCaM CaMCa 2+

0.5 µM1 µM100 µM Control CaM IICR is inhibited by CaM and CaM 1234 Time (s) ATP Ca 2+ i (nM) CaM 1234 CaM CaM 1234 Control

 CaM is not the Ca 2+ sensor for the IP 3 R 200 nM IP 3 CaM 1234 CaM [Ca 2+ ] (µM) 45 Ca 2+ flux 0.11 IICR is inhibited by CaM and CaM Ca 2+ release (%)

Half CaM’s CaM C-CaM N-CaM 3 HIP 3 binding control 45 Ca 2+ flux control Both CaM lobes are necessary to inhibit the IP 3 R

Ca 2+ Closed « square » Open « windmill » IICR [Ca 2+ ] (nM)300 Inactive Other regulators kinases phosphatases The N-terminal Ca 2+ -independent CaM-binding Site on the IP 3 R is Responsible for CaM Inhibition, even though this Inhibition Requires Ca 2+

IP 3 R1IP 3 R3 suramin

Summary  Two CaM-binding sites on the IP 3 R Ca 2+ dependent in the regulatory domain Ca 2+ independent in the N-terminus  CaM inhibits IICR only in the presence of Ca 2+  CaM inhibits IICR by lowering the affinity for IP 3, CaM is not the Ca 2+ sensor

Introduction: Calcium signalling Inositol trisphosphate receptor (IP3R) Results: Conclusions Perspectives Regulation of the IP3R by Ca2+ and calmodulin Regulation of intracellular Ca2+ release by neuronal Ca2+ binding proteins A novel Ca2+-induced Ca2+ release mechanism in A7r5 and 16HBE014-cells

Regulation of calcium release by neuronal Calcium Binding Proteins (CaBP)

CaM CaM-like L-CaBP1 S-CaBP1 Caldendrin S-CaBP5 S-CaBP2 L-CaBP2 S-CaBP3 CaBP3 GCAP GCAP3 GCAP2 Recoverin Visinin Neurocalcin VILIP3 VILIP1 VILIP2 NCS1 EF1EF2EF3EF4 CaM EF1EF2EF3EF4 CaBP1 EF1EF2EF3EF4 CaBP2 EF3EF4 CaBP3 EF1EF2EF3EF4 CaBP4 EF1EF2EF3EF4 CaBP5 Adapted from Haeseleer et al., 2000 CaBP NCS

Why so many CaBPs….? Cellular localisation Ca 2+ myristyol switch Burgoyne et al., 2004 NUCLEUS Golgi Low Ca 2+ NUCLEUS High Ca 2+ Golgi * * * * *

Exocytosis in Endocrine cells Exocytosis in Synapses Channel regulation Basal Ca2+ NCS1VILIP-1CaMSynaptotagmin Ca 2+ bound -log[Ca 2 ] + Adapted from Burgoyne and Weiss 2001 Why so many CaBPs….? Cellular Localisation and….

CaBPs agonist of the IP 3 R? Taken from Yang et al., 2002 CaBPs are agonists of the IP 3 R CaBPs bind to N-terminus of the IP 3 R CaBPs binding is Ca 2+ dependent CaBPs co-localize with the IP 3 R

sCaBP1 GST GST GST CaBP1 binds to the IP 3 R NH 2 COOH ER CYT IP 3 binding core ( ) caldendrin lCaBP1 sCaBP1

A B C E D F CaM sCaBP1 ABCDEF ABCDEF + Ca 2+ EGTA CaBP1 binds to a similar region of the IP 3 R as CaM

CaBP 1/11/21/41/5 1/6 1/8 1/10 1/3 CaBP Ratio of CaBP: peptide B Band intensity Peptide B: CaBP + Calcium + EGTA Binding of CaBP to the IP 3 R is Ca 2+ independent

EF1EF2EF3EF4 CaBP1 lCaBP1 sCaBP1 Cellular localization of CaBP1

sCaBP 0.5µM 1µM 100µM ATP Control lCaBP Time (s) Ca 2+ i (nM) Both Long and Short CaBP1 inhibit IICR

SCaBP1 (n=22) LCaBP1 (n=17) Control (n=44) * * * *

CaBP overexpression inhibits IP 3 Ester induced Calcium release  M InsP 3 ester SCaBP1 Control time (s) Ca2+ i (nM) CaBP acts directly on the IP 3 R

CaBP1 inhibits IP 3 binding to the IP 3 R control sCaBP1Ca 2+ sCaBP1 100 [ 3 H]IP 3 Binding (% vs control) IP 3 binding 45 Ca 2+ flux 45 Ca 2+ -release (%) [IP 3 ] (µM) control sCaBP , CaBP acts directly on the IP 3 R by inhibiting IP 3 binding

EF1EF2EF3EF Time (s) 0 Ca 2+ i (nM) µM ATP Control CaBP 134 CaBP1 inhibits IICR independent of Ca 2+ binding (1) % responsive cells ATP (  M)

 CaBP1 is not a Ca 2+ sensor for the IP 3 R 200 nM IP 3 CaBP1 134 CaBP1 [Ca 2+ ] (µM) 45 Ca 2+ flux (%) CaBP1 inhibits IICR independent of Ca 2+ binding (2)

IICR is inhibited by CaBP1 CaBP1 binds to the receptor in a Ca 2+ independent manner resulting in inhibition of IP 3 binding to its receptor. To summarise.. But, how is CaBP1 activity regulated? CaBP does not activate Ca 2+ release as previously reported

sCaBP1sCaBP1-G2A lCaBP1-G2AlCaBP1 Membrane Targeting of CaBP may regulate its activity (1) EF1EF2EF3EF4 CaBP1-G2A

ATP (µM ) Membrane Targeting of CaBP1 may regulate its activity (2) time (s) Control sCaBP -G2A Ca 2+ i (nM) % responsive cells ATP (  M) Peak amplitude (nM) * * * *

32 P- CaBP YFPS120A wt Time (s) Ca 2+ i (nM) ATP (µM) 100 Control CaBP1 S120A ATP (  M) Peak amplitude (nM) * * % responsive cells * * * Phosphorylation of CaBP1 decreases it’s potency EF1EF2EF3EF4 S120A CaBP1 S120A Casein kinase [ST]xx[DE]

10µM CCh 0.5mM Caf 1mM Caf 2mM Caf [ C a 2 + ] i ( n M ) CaBP1 does not Affect Ca 2+ release through RyRs Time (s) Control sCaBP1

Summary  CaBP inhibits IICR  CaBP binds to the IP 3 R inhibiting IP 3 binding  CaBP activity is Ca 2+ independent  Myristoylation is not essential for CaBP activity, although it may have a regulatory role  Phosphorylation of CaBP decreases it’s potency  RyRs are not modulated by CaBP

CaBP1CaM Neurons IP 3 RRyR In Neurons: CaM preferentially modulates RyRs CaBPs preferentially modulate IP 3 R? Conclusions

The End

VGCC LGCC SOCC (TRP) MSCC PMCA NCX IP 3 RRYR ER/SR SERCA IP 3 R Golgi PMR1 Mitochondria NCX Uniporter Others?? Buffers Second messenger

Control Calbindin 0.5µM ATP1µM ATP100µM ATP Time (s) Ca2+ i (nM) Inhibition of IICR by CaBP is not due to Calcium Buffering

% responsive cells  M1M1M0.5  M 0 Peak Amplitude (nM) ATP Control Calbindin Calbindin Decreases Peak Response without decreasing number of responsive cells

Introduction: Calcium signalling Inositol trisphosphate receptor (IP3R) Results: Conclusions Perspectives Regulation of the IP3R by Ca2+ and calmodulin Regulation of intracellular Ca2+ release by neuronal Ca2+ binding proteins A novel Ca2+-induced Ca2+ release mechanism in A7r5 and 16HBE014-cells

Introduction: Calcium signalling Inositol trisphosphate receptor (IP3R) Results: Conclusions Perspectives Regulation of the IP3R by Ca2+ and calmodulin Regulation of intracellular Ca2+ release by neuronal Ca2+ binding proteins A novel Ca2+-induced Ca2+ release mechanism in A7r5 and 16HBE014-cells