Download Cellular Pathophysiology of Insulin Resistance

Lipodystrophy:
Metabolic and Clinical
Aspects
Resource Room Slide Series
Cellular Pathology of Insulin
Resistance in Lipodystrophy
Robert R. Henry, MD
Professor of Medicine
University of California, San Diego
VA San Diego Healthcare System
San Diego, CA
Theodore P. Ciaraldi, PhD
Project Scientist, UCSD
La Jolla, CA
Disclosures
• Dr. Henry:
– Grants: AstraZeneca, Bristol-Myers Squibb, Eli Lilly,
Medtronic, and Sanofi
– Consulting: Boehringer Ingelheim, Eli Lilly, Gilead,
Intarcia, Isis, Novo Nordisk, Roche/Genentech, and
Sanofi
– Advisory board: Amgen, AstraZeneca, Boehringer
Ingelheim, Bristol-Myers Squibb, Daiichi Sankyo,
Elcelyx, Eli Lilly, Gilead, Intarcia, Johnson &
Johnson/Janssen, Merck, Novo Nordisk,
Roche/Genentech, Sanofi
• Dr. Ciaraldi
– There are no relevant financial relationships to
disclose.
Objectives
• Understand the role of ectopic fat storage in the
development of insulin resistance
• Understand the nature of bi-directional signaling
that occurs between adipose tissue and other
organs: muscle, liver, and pancreas
• Recognize how post-translational modifications
(PTMs) affect both signaling pathways and gene
regulation
Overview
1. Fat storage
• Where and how?
• Fat metabolism in skeletal muscle
• Disordered fat metabolism
2. Insulin signaling
•
•
•
•
Target tissues and responses
Pathways
PTMs
Disordered insulin signaling
3. Adipose tissue-skeletal muscle communication
• Activation of stress kinases
• Altered phosphorylation of insulin receptor substrate 1
(IRS-1): consequences
• Altered PTMs of transcription factors: consequences
Body Fat Distribution
Healthy
Subcutaneous
obesity
Visceral
obesity
Lipodystrophy
Definitions
Ectopic:
Ectopic Fat:
Occurring in an abnormal
position or unusual manner
or form*
Abnormal fat accumulation
other than in adipose tissue
(eg, skeletal muscle, heart,
liver, pancreas)
* Merriam-Webster dictionary
Fat Distribution Between Tissues
Adipose Tissue
Compartment
Plasma
Muscle
Compartment
Lean
Subcutaneous Obesity
Visceral Obesity
Lipodystrophy
Unger RH. Trends Endocrinol Metab. 2003;14:398-403.
Intramyocellular Lipid
Relationship to Insulin Sensitivity
●
Insulin Sensitivity
(clamp log10 mol/l) (mg/min kg FFM + 17.7)
0.9
r = -0.53 P<0.0006
0.8
0.7
0.6
0.5
0.4
0.3
0.2
0.1
Current Opinion in Pharmacology
1
2
3
4
5
6
7
8
9
10
Skeletal Muscle-Associated Triglyceride
(mmol/g wet weight of tissue)
Nawrocki AR, Scherer PE. Curr Opin Pharmacol. 2004;4:281-289.
Kelley DE, Goodpaster BH. Diabetes Care. 2001;24:933-941.
Lipid Droplets (LDs)
Multi-Faceted Organelles for Lipid Storage and Mobilization
• Outer phospholipid monolayer
• Neutral lipid core: triglycerides, cholesterol esters
• Monolayer studded with LD proteins:
– Lipases and activators
– Adipocyte triglyceride lipase (ATGL)
– Hormone sensitive lipase (HSL)
– Comparative gene identification-58 (CGI58), activator
of ATGL
– Perilipins (PLINs) 1-5: regulate access of lipases to lipid
tissue-specific expression
– LDs permit organization and regulation of lipid storage
and mobilization
Lipid Storage in Cells
Adipocyte
Skeletal muscle
LD
LD
LD
- HSL
- ATGL
- CGI58
- PLIN 1
- PLIN 2
LD
- PLIN 5
Sources and Fates of Lipids and Fats
Tissue Specificity
Tissue
Lipid Source
Fate
Adipose tissue
Internal stores
Circulation
Synthesis
Lipolysis and release to
circulation
Structural
Skeletal muscle
Circulation
Internal stores
(Limited)
Oxidation
Structural
Liver
Circulation
Internal stores
(Limited)
Synthesis
Oxidation
Lipoprotein production
Structural
Pancreas
Circulation
Oxidation
Fat Metabolism in Muscle
Healthy
Hyperlipidemia
FFA
FFA
FATP1
FAT
FABPpm
FATP1
CO2
FABPpm
CO2
Ceramide
FFA
Ceramide
FFA
mito
LCFACoA
FAT
LD
Diffusion
DAG
DAG
LCFACoA
Protein-mediated transport and trafficking
Fats and Metabolites in Muscle
Change in Lipodystrophy

Intramyocellular lipid
 
Triglyceride (TG)
Diacylglycerol (DAG)
 *
Long Chain Fatty Acyl CoA (LCFA-CoA)
Ceramide

 
Acylcarnatines

CO2

* Degree of fatty acid (FA) saturation altered in insulin-resistant conditions
Fat Cell Functions
Then
Lipoprotein
LPL
FFA
FFA
FFA
(in lipodystrophy)
TG
Glucose
LD
Adipose Tissue Functions
Now
Angiotensin II
Visfatin
CRP
PAI-1
Increased in lipodystrophy
FAT
FFA
IL-6
MCP-1
TNF-α
Decreased in Lipodystrophy
Adiponectin
Leptin
Resistin
Summary, Part 1
• In healthy individuals, lipid is stored predominately
in adipose tissue, with subcutaneous adipose
tissue > visceral adipose tissue.
• Lipid storage in muscle, liver, and pancreas is
limited and present primarily to meet energetic and
structural needs.
• Lipid storage in tissues is tightly regulated,
primarily through the actions of proteins associated
with LDs.
Summary, Part 1, cont.
• Loss of the storage capacity of adipose tissue,
such as in lipodystrophy, leads to increased lipid
stores in other tissues (ectopic fat).
• Lipid oversupply results in altered/incomplete FFA
oxidation.
• Specific FA metabolites can have deleterious
effects on cellular function, including secretion
(eg, adipokines).
Insulin Target Tissues – 1
Tissue
Skeletal muscle
Adipose tissue
Response
 Glucose uptake
 Glycogen synthesis
 Lipolysis
 Lipogenesis
 Glucose production
Liver
 Lipogenesis
 Lipoprotein production
 Glucose oxidation
Heart
 FFA oxidation
 Hypertrophy
Insulin Target Tissues – 2
Tissue
Brain
Response
 Appetite
 Sympathetic tone
Vasoconstriction
Endothelium
Vasodilation
Leukocyte adhesion
Macrophage
 Low density lipoprotein uptake
Insulin Signaling
Cast of Players
IR
Insulin Receptor
GLUT4
Glucose Transporter 4
IRS (1-5)
Insulin Receptor Substrate
GSK3
Glycogen Synthase Kinase 3
PI3-K
Phosphoinositide 3 Kinase
(p85 & p110 kDa Subunits)
Grb2
Growth Factor Receptor Bound-2,
Scaffold Protein
PDK1
Phosphoinositide-Dependent Kinase
SOS
Son of Sevenless, Scaffold Protein
Also known as Protein Kinase B
ERK
Extracellular Regulated Kinase
Akt
aPKC
Atyptical Protein Kinase C
mTOR
Mammalian Target of Rapamycin
AS160
Akt Substrate of 160 kDa
Shc
Src homology 2 and collagen-like
Insulin Receptor
-S-S-
 subunit
Plasma Membrane
Insulin Binding
- Transmembrane Region
ß subunit
Y953
Y960
- Juxtamembrane Region
Y1146
Y1150
Y1151
- Kinase Regulatory Region
Y1316
Y1322
- C-Terminal Regulatory Region
Adapted from Ciaraldi TP. In Principles of Diabetes Mellitus. 2nd ed.
Poretsky LO, ed. New York, Springer,2009, p. 75-87.
Principles of Insulin Signaling
• The IR can phosphorylate both itself and other
proteins (eg, IRS) on the amino acid tyrosine.
• Phosphorylation creates recognition sites for IRS
and other proteins to serve as scaffolds,
recruiting other molecules into signaling
complexes.
• Phosphorylation on other sites can oppose
complex formation.
Principles of Insulin Signaling, cont.
• Intracellular localization of these multi-molecular
signaling complexes plays an important role in
the subsequent pathways activated.
• Phosphorylation is just one of a number of posttranslational modifications (PTMs) that can
influence complex formation, sub-cellular
localization, enzyme activity, and stability or
degradation of the protein(s).
PTMs of Proteins
Modification
Enzyme
Responsible
Kinase (eg, IR)
P
Phosphorylation
Phosphate
Phosphatase
HAT
Ac
Acetylation
Acetyl group
HDAC
OGT
O-GlcNAC
O-linked-Nacetylglucosamine
O-GlcNAcylation
OGA
E1, E2, E3
Ub
Ub
Ubiquitination
Ub
Ubiquitin
DUB
E1, E2, E3
SUMO
SUMOylation
SENP, DeSI
Small ubiquitinrelated modifier
Phosphorylation of IRS-1
IR
Y613 Y623
NH2
PH
PTB
PI3K binding
IRS-1 has no intrinsic enzymatic activity
PH – pleckstrin homology domain, binds phosphoinositides – PIPx
PTB – phosphotyrosine binding domain
COOH
IRS-1 as a Molecular Scaffold
IR
Y613 Y623
NH2
PH
PI3K binding
PTB
p85
Grb-2
COOH
Insulin Signaling: Metabolism
Insulin
PI(3,4,5)P3
PI(4,5)P2
IRS
p85
PDK1
Insulin Receptor
p110
aPKC?
Akt
GSK3
_
GS
-pS
AS160
GS
-pY
Rab-GTP
GLUT4
GLUT4
Vesicle
Adapted from Fröjdö S, Vidal H, Pirola L. Biochim Biophys Acta. 2009;1792:83-92.
Mitogenesis & Gene Expression
Insulin
PI(4,5)P2
PI(3,4,5)P3
Insulin Receptor
Grb2
SOS
IRS
p85 p110
PDK1
Shc
Akt
GSK3
Erk 1/2
p70S6K
mTOR
Transcription
Factors
Nucleus
Fröjdö S, Vidal H, Pirola L. Biochim Biophys Acta. 2009;1792:83-92.
Insulin Action in Lipodystrophy
and Type 2 Diabetes
Muscle
Adipose Tissue
IR Binding

 
IR Kinase


IRS Phosphorylation


IRS1 – PI-3K Activity


Akt Phosphorylation
 

aPKC Activity

AS160 Phosphorylation


GLUT4 Abundance

 
GLUT4 Translocation

 
GSK3


Erk 1/2 Activity


Change expressed relative to healthy individuals
Type 2 Diabetes
Lipodystrophy
PTMs of Transcription Factors:
Regulation of Gene Expression
Transcription Factor
Modification
Phosphorylation
FOXO1
Effect on Activity


Acetylation

O-GluNAcylation

Phosphorylation
SREBP1c
Insulin Effect
Acetylation
 
 



SUMOylation
Phosphorylation
PPARγ

SUMOylation

Phosphorylation

Acetylation
NF-кB

 
Ubiquitination

O-GluNAcylation

Summary, Part 2
• Insulin is a pleotropic hormone, generating an
array of responses in multiple tissues.
• Insulin signaling is initiated by binding to its
receptor and stimulation of IR tyrosine kinase
activity.
• Phosphorylation cascades regulate the assembly
and subcellular localization of multi-molecular
signaling complexes.
Summary, Part 2, cont.
• Different substrates and signaling complexes
mediate insulin signaling to regulation of
metabolism and gene expression/mitogenesis.
• Disruption of phosphorylation cascades, either
by phosphorylation at alternative sites or other
PTMs, can lead to insulin resistance.
Stress-Activated Kinases
Kinase
Substrates
Activators
Erk 1/2
(p44/42 Mitogen Activated Protein Kinase)
C-Jun
p53
IKKα
Insulin
Thrombin
p38 Mitogen Activated Protein Kinase (p38)
Caspase 3/6
SP1
CEBP
FFA
Glucose
Inflammatory
cytokines
IкB Kinase (IKK)
IkBα
Inflammatory
cytokines
FFA
c-Jun NH2 Terminal Kinase (JNK)
IRS-1
c-Jun
p53
Inflammatory
cytokines
FFA
Phosphorylation of IRS-1
Positive
Negative
Mixed
IR
Y613 Y623
NH2
PH
PI3K binding
PTB
S307 S312 S323 S332 S616 S636
JNK
JNK
GSK3
mTOR
mTOR
ERK
S731
mTOR
COOH
S794
AMPK
IKKß
PKC
PKC
p70S6K
p70S6K
S1101
PKC
Phosphorylation of IRS-1, cont.
Kinase
Site
Effect on Activity
Akt
S522 , S629
 
JNK
S307 , S312
 
mTOR
S307 , S731
 
IKKß
S312

PKCα
S24

PKCΘ
S312 , S1101
 
PKCζ
S323

p70S6K
S312

ERK
S636

GSK3
S322

AMPK
S794

PTMs of Transcription Factors:
Regulation of Gene Expression
Transcription Factor
FOXO1
SREBP1c
PPARγ
NF-кB
PTM
Effect on Activity
Phosphorylation

Acetylation

Phosphorylation

Acetylation

SUMOylation

Phosphorylation

SUMOylation

Phosphorylation (IкBα)

Acetylation

Ubiquitination

Summary, Part 3
• Kinases activated by FFAs and inflammatory cytokines
can phosphorylate IRS-1 on serine residues to impair
downstream insulin signaling.
• Phosphorylation of transcription factors (TFs) can either
stimulate or impair their activity, depending on the site
modified.
• Phosphorylation and other PTMs of TFs can influence
subcellular localization, protein stability, and/or
transcriptional activity.
• Phosphorylation of IkB leads to its degradation,
releasing NFkB to move into the nucleus and stimulate
the transcription of proinflammatory genes, including
cytokines and chemokines, maintaining a vicious circle.
Hyperlipidemia and Inflammation-mediated
Insulin Resistance
FFA
p38
DAG
LCFACoA
Ceramides
JNK
IRS
IKKß
Cytokines
Degradation
IkB
NFkB
NFkB
Proinflammatory Genes
A Downward Spiral
Lipodystrophy to Insulin Resistance
Ectopic Fat
AT
Circulating FFA
Activation of
Stress Kinases
Phosphorylation
of IRS-1, etc.
Altered FA
Metabolism
Circulating FFA
Inflammatory Cytokines
Insulin Resistance
Insulin Secretion