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Transcript
Aberrant Cell Signaling and
the Related Disorders
Jimin Shao (邵吉民)
Professor, Dept. Pathology and Pathophysiology
Tel: 88208209
E-mail: [email protected]
(1) Causes
• Gene mutation-- Function loss or gain
Quantity change of signaling pathway proteins
Activity change of signaling pathway proteins
• Autoimmune diseases
• Secondary changes
(2) Pathogenesis
Abnormality: Ligands, Receptors, Post-receptor components, Effectors
 Down-regulation / interruption of signaling
• Signal Insufficiency
• Receptors down-regulation/desensitization: decreased quantity, binding affinity,
inhibitory Ab, cofactor disorders, function loss, etc.
• Defects in Adaptors, Signal transducers, TFs, other Effectors, etc.
Up-regulation / over-activation of signaling
•
Signal Excess
•
Receptor up-regulation, hypersensitivity, stimulatory Ab, etc
•
Signal transducers, TFs: over-expression, persistent activation, etc.
1. Aberrant Signal
(1) Aberrant Signal (Signal Insufficiency)




Insulin receptor (IR): heterotetramer (2, 2)
Insulin binding leads to change in conformation
Activates IR -subunit (PTK activity)
IR-subunit phosphorylates Tyr residues on cytoplasmic domains
as well as downstream substrates (IRS)
Viral infections or other
damages to pancreatic -cell
insulin production
hyperglycemia
Diabetes (Type I)
(2) Aberrant Signal (Signal Excess)
ischemia, epilepsy, neurodegenerative diseases
extracellular glutamate/aspartic acid
NMDAR activation
(N-methyl-D-aspartate receptor, Ion Channel Linked Receptor)
Ca2+ influx
[Ca2+] , activation of enzymes
excitatory intoxication
2. Aberrant Receptor in Cell Signaling

Disturbance of receptors can occur in:


gene level,
Protein level: synthesis, post-translational modification, conformation,
oligomerization, translocation, endocytosis, degradation, and etc.

Receptor alterations in number, structure, function, and
regulation lead to:




down-regulation: decrease in number of receptors
desensitization: decreased response to ligand stimulation
up regulation: increase in number of receptors
hypersensitivity: increased response to ligand stimulation,
or self-activation without ligands
 Receptor diseases:
receptor alterations --- changes of ligand-receptor signaling --- abnormal
cellular effects --- diseases
(1)Receptor Gene Mutation
Insulin
Genetic insulin-resistant diabetes
IR gene mutations
Activate IR(RPTK)
IRS
PI3K
Ras/Raf/MEK/ERK
Glu Transport & Utilization,
Glycogen Synthesis, etc
Cell proliferation
Disturbances in
synthesis
transfer to the membrane
affinity to insulin
PTK activity
proteolysis/degradation
Type II Diabetes
(2) Autoimmune diseases-thyropathy
Stimulatory Ab
Blocking Ab
TSH-R(GPCR)
30~35
residues
Gs
TSH-R
Gq
AC
(295~302
385~395
residues )
PLC
cAMP
IP3
Ca2+
DAG
Binding of TSH to R
PKC
Thyroid proliferation & secretion of thyroxine 
hypothyroidism
hyperthyroidism
Graves病(弥漫性毒性甲状腺肿)




刺激性抗体模拟TSH 的作用
促进甲状腺素分泌和甲状腺腺体生长
女性>男性
甲亢、甲状腺弥漫性肿大、突眼
桥本病 (Hashimoto’s thyroditis,慢性淋巴细胞性甲状腺炎)




阻断性抗体与TSH受体结合
减弱或消除了TSH的作用
抑制甲状腺素分泌
甲状腺功能减退、黏液性水肿
(3)Secondary Abnormality in Receptors
Heart failure, Myocardial hypertrophy
-adrenergic receptors (GPCR)
down regulated or desensitized
Reaction to catecholamines
Myocardial contraction
Alleviate
myocardial lesion
Accelerate
heart failure
受体异常疾病
分类
累及的受体
主要临床特征
家族性高胆固醇血症
LDL受体
血浆LDL升高,脂质代谢紊乱,动脉粥样硬化
家族性肾性尿崩症
ADH V2型受体(GPCR)
男性发病,多尿、口渴和多饮
视紫质
进行性视力减退
视锥细胞视蛋白
色觉异常
IL-2受体γ链
T细胞减少或缺失,反复感染
Cccccccccccccccc II型糖尿病
胰岛素受体(RTK)
高血糖,血浆胰岛素正常或升高
ccc核受体异常 ccc雄激素抵抗综合征
雄激素受体
不育症,睾丸女性化
cccccccccccccccc维生素D抵抗性佝偻病
维生素D受体
佝偻病骨损害,秃发,继发性甲状旁腺素增高
Cccccccccccccccc甲状腺素抵抗综合征
β甲状腺素受体
甲状腺功能减退,生长迟缓
cccccccccccccccc雌激素抵抗综合征
雌激素受体
骨质疏松,不孕症
Ccccccccccccccc 糖皮质激素抵抗综合征
糖皮质激素受体
多毛症,性早熟,低肾素性高血压
遗传性受体病
膜受体异常
c视网膜色素变性
Cccccccccccccccc 遗传性色盲
11111111111111
严重联合免疫缺陷症
自身免疫性受体病
cccccccccccccccc重症肌无力
nAch受体
活动后肌无力
cccccccccccccccc自身免疫性甲状腺病
刺激性TSH受体(GPCR)
抑制性TSH受体
甲亢和甲状腺肿大
甲状腺功能减退
ccccccccccccccccII型糖尿病
胰岛素受体
高血糖,血浆胰岛素正常或升高
cccccccccccccccc艾迪生病
ACTH受体
色素沉着,乏力,血压低
继发性受体异常
ccccccccccccccc心力衰竭
肾上腺素能受体
心肌收缩力降低
ccccccccccccccc帕金森病
多巴胺受体
肌张力增高或强直僵硬
ccccccccccccccc肥胖
胰岛素受体
血糖升高
ccccccccccccccc肿瘤
生长因子受体
细胞过度增殖
3. Aberrant G-protein
in Cell Signaling
(1) G-protein gene mutation
Pituitary tumor:
Gs gene mutation At Arg201 or Gln227
Hypothalamus
GHRH
Pituitary gland
GHRH-R
GTPase activity
Persistent activation of Gs
Persistent activation of AC
Gs
cAMP
Ac
Pituitary proliferation and secretion
cAMP
GH
Acromegaly in adults
Gigantism in children
(2) G-protein modification
Cholera toxin
intestinal epithelia
Gs ribosylation at Arg201
Inactivation of GTPase
Persistent activation of Gs and Ac, cAMP
secretion of chloride into the lumen,
inhibition of sodium uptake from the lumen,
Large volumns of fluid into the lumen of the gut
Diarrhea and dehydration
Circulation failure
4. Aberrant intracellular Signaling
• The intracellular signaling involves
-- various messengers, transducers, transcription factors, and others.
• Disorders can occur in any of these settings, e.g.
-- Stimulation of NF-B is seen in various inflammatory responses
-- Calcium overload is a general pathological process in various
diseases;
-- The level of NO is positively correlated with ischemic injury;
---Enhancement of multiple proliferating signals in
Cancer
Ligands (GFs): e.g. EGF
Receptors (overexpression, activation of PTK): e.g. EGFR
Intracellular signal transducers:
Ras gene mutation Ras-GTPase
Ras activation
Raf
MEK
ERK
Proliferation
TUMOR
5. Multiple Abnormalities in
Signaling Pathway
6. Relationship between Stimulants and
Pathological Effects
(1) Same Stimulant Induces Different Responses
(the same stimuli can act on different receptors)
(2) Different Signals Induces the Same Pathologic
Response
(different receptors use the same pathway or by crosstalk)
(3) Different receptors use same pathways
GPCR, RTK, Cytokines Rs
PLC
PKC
Ras
PI-3K
Raf
PKB
MEK
ERK
(4) Cross talk—
how hypertension leads to myocardial hypertrophy?
Mechanic stimuli
Na+, Ca2+ influx
Na+-H+ exchange
Alkalization
NE, AT-II
GF TGF-
PLC
TPK PSTK
Ca2+/PKC
Ras Smad-P
Raf
MAPK
Transcription factors, target genes
Target proteins
Myocardial Hypertrophy
7. Principles for Treatment of
Aberrant Signaling-related Diseases
Stratagy:
•
•
•
To regulate the level of extracellular molecules
To regulate the structure and the function of receptors
To regulate the level and modifications of modification enzymes,
intracellular messengers, signal transducers, transcription factors,
etc
Target therapy:
•
•
Breast cancer:
EGFR overexpression –Herceptin (mAB)
Chronic myeloid leukemia (CML):
Bcr-Abl (abnormal tyrosine kinase) — Gleevec (small compound
inhibitor)