2.3 維持酵素活性Maintain activity

2 酵素活性測定法
Enzyme activity assay methods
● 2.1 催化反應 Catalytic reaction
活性測定時要注意一些基本原則
● 2.2 酵素活性分析 Enzyme assay methods
反應速率 = 生成物 (P) / 時間 (t)
● 2.3 維持酵素活性 Maintain activity
很多酵素在細胞外容易失去活性
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Use excess substrate
[substrate] = 10 x Km
-
Substrate
Enzyme
Product might
inhibit enzyme
(feedback inhibition)
Product
NAD+
Remove product
Measured directly
NADH
Changed to visible
Enzyme catalysis and detection methods
耦合反應
■
酵
素
反
應
及
偵
測
方
法
Measurable?
Coupling reaction
Dehydrogenase
Product transformed
into measurable form
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■ 基質量使用十倍 Km
[Substrate] = 10 Km
Velocity
Vmax
1/2
Km
10 Km
[substrate]
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■ 酵素活性測定 Determine enzyme activity (SEPt)
Optimized enzyme concentration
Substrate
excess
10 x Km
E
Product
measurable
pH
t
酸鹼度
Proper reaction time
P
vo =
t
Temperature
溫度
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■ 反應速率需成線性 True velocity of the reaction
Product
True
velocity
False
observation
p
p
vo =
t
slope
t
Time
t
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2.2 酵素活性分析 Enzyme assay methods
● 2.2.1 酵素活性測定方法 Assay methods
在一定時間內測得生成物的產量
● 2.2.2 中止酵素反應方法 Stop the reaction
中止酵素的方法不得破壞生成物或干擾測定
● 2.2.3 連續測定法 Continuous measuring
連續測定可不用刻意中止酵素反應
● 2.2.4 澱粉磷解脢活性分析 Assay for L-SP
以生化方法可以偵測到澱粉磷解脢的活性
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2.2.1 酵素活性測定方法 Assay methods
● a. 直接測定生成物 Measuring product directly
酒精去氫脢 (alcohol dehydrogenase, deHase)
Alcohol ＋ NAD+ → Acetaldehyde ＋ NADH ＋ H+
● b. 耦合反應法 Coupling reaction
S → P → Q 可耦合到去氫脢反應 (coupled to deHase)
● c. 化學測定法 Chemical method
● d. 放射線測定法 Tracer method
● e. 測壓法 Manometry (for gaseous product)
● f. 電極 Electrode (for pH or O2 change)
● g. HPLC 檢定法 Your last choice
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■ 輔脢 NADH 作用機制 Action of coenzyme NADH
NADP+
Oxidized form
NADPH Reduced form
Adapted from Alberts et al (2002) Molecular Biology of the Cell (4e) p.86
H
H
H
CONH2
CONH2
+
N
N
P O
P O
Ribose
Ribose
H
Adenine
P O
Adenine
P O
Ribose
Ribose
O
O
P
P
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■ Coenzyme NADH
NAD+/NADH 的轉換可以
耦合 340 nm 吸光度變化
NAD+
NADH
340 nm
NAD+
吸
光
度
A
340 nm
Dehydrogenase (去氫脢)
Glyceraldehyde-3-P deHase
● Dehydrogenases use NADH
or NADPH as coenzyme
● Have similar NAD+ Binding
domain (Convergent evolution)
NADH
240 280
320
360
400
Wave length (nm)
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Glyceraldehyde3-phosphate
dehydrogenase
NADH
NADH
Binding
Domain
(conserved)
G-3-P
substrate
Binding
Domain
(variable)
A typical dehydrogenase molecule contains two domains
Kleinsmith & Kish (1995) Principles of Cell and Molecular Biology (2e) p.25
■
一
個
典
型
的
去
氫
脢
■ GUS activity assay - using synthetic substrate
Substrate (colorless)
COOH
O O
HO
NO2
OH
p-Nitrophenyl β-D-glucuronide
(pNPG)
COOH
O OH
+ H2O
GUS
OH
Products (yellow)
HO
OH
+
HO
NO2
OH
β-D-Glucuronic acid
p-Nitrophenol
(yellow)
415 nm
GUS (glucuronidase) is extensively used for a reporter in cloning.
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■
酵
素
偵
測
方
法
Enzyme
Measure directly
Product
Chemical
method
Enzyme detection methods
Measured directly
耦合反應
NAD+
Tracer method
Manometry
Electrode
HPLC 檢定法
Coupling reaction
NADH
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■ Coupled to dehydrogenase (NAD+-NADH)
Hexokinase
Glucose + ATP
Glucose-6-P + ADP
NAD+
Glc-6-P deHase
NADH
6-P-Gluconic acid
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■ 轉化脢 Invertase (IT)
Sucrose
Non-reducing
sugar
IT
Glucose + Fructose
Reducing sugars
Reducing
Power
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■ 放射線測定法 Using radioactive tracer
Glutathione
γ-Glu-Cys-Gly
N
Artefact
假象
PCS
X2
Phytochelatin
γ-Glu-Cys-γ-Glu-Cys-Gly
C
Carboxypeptidase Y
It is safer to measure phytochelatin directly by HPLC
+
Isolated for
detection
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A sensor to monitor the quality of meat
Enzyme electrode
Oxygen electrode
Oxygen
consumption
Hypoxanthine
Hypoxanthine oxidase
牛頓 (1985) no. 23 p.108
2.2.4 澱粉磷解脢活性分析 Assay for L-SP
Starch
Phosphate
+
P
n
P
Phosphorolysis
P
Starch-binding site
Starch-binding site
Catalytic site
Catalytic site
Starch biosynthesis
+
n-1
P
Glc-1-P
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■ Coupled to dehydrogenase
Starch phosphorylase (phosphorolysis)
Starch (n) + Pi
Glc-1-P + Starch (n-1)
Phosphoglucomutase
Glc-6-P
Glc-6-P deHase
NAD+
NADH
6-P-Gluconic acid
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■
澱
粉
磷
解

活
性
分
析
及
干
擾
A
B
Activity staining
Activity assay and interference
Glc-1-P
SP
Ph
Primer
BA
BA
SP
Native PAGE
Glucose
+
Pi
I2
Some other enzymes
might interfere assay
Direct observation of the color product
Some other enzymes might lead to false (+) or (-) results
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2.2.2 中止酵素反應方法 Stop enzyme reaction
● How to denature the enzyme effectively ?
● Change pH
TCA
Chemical
Boiling Physical
● Rapidly heating
● Add denaturant
SDS
Chemical
● Add metal chelator
EDTA Chemical
● Add enzyme inhibitor PMSF Chemical
● Add non-radioactive
Physical
substrate (pulse-chase)
● The product should not be destroyed
● No interference to the detection method
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Mathews & van Holde (1990) Biochemistry (1e) p.200, Fig. 6.25
■
蛋
白
質
的
四
級
構
造
1
Peptide bond
Hydrogen bond
2
3
Disulfide bond
Hydrophobic bond
Hydrogen bond
Four levers of protein structure
4
■ SDS 在蛋白質表面均勻敷上一層負電
Native protein
Protein is denatured to linear form
SDS
Hydrophobic core
boiling
Its surface covered with negatively
charged SDS uniformly
+ Mercaptoethanol: to break the disulfide bonds
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Guanidine HCl
NH2+
NH2- C -NH2
Mercaptoethanol
HOCH2CH2SH
SDS
SO4- -(CH2)11CH3
Common denaturants for proteins
Non-polar
tail
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Polar
head
=
Urea
O
NH2- C -NH2
=
■
常
見
的
變
性
劑
=
O
-N H 2
NH 2-C
H-bonds
stabilize
secondary
structure
Mathews et al (2000) Biochemistry (3e) p.164
β sheet
O
H2
N
-C
2
H
N
α helix
=
■
蛋
白
質
二
級
構
造
■ Pulse-chase
Pulse
Chase
Pulse
To measure the flow speed of water in a glass tube
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■ 高爾基氏體的蛋白質運送 Golgi transportation
Inner side
Outer side
Alberts et al (2002) Molecular Biology of the Cell (4e) p.736-737
2.3 維持酵素活性 Maintain enzyme activity
● 2.3.1 緩衝液 Buffer
可維持穩定的酸鹼度及離子濃度以保酵素活性
● 2.3.2 試劑的保存 Reagents
試劑要依指示保存在適當的地方
● 2.3.3 酵素活性之維持 Maintain the activity
注意酵素失活的原因有助保持其最高活性
● 2.3.4 酵素活性單位 Enzyme activity unit
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■ 弱酸鹼可作為緩衝分子 Buffer is weak acid/base
Ka
AH
CH3COOH
H-H
equation
Strong acid
-
A + H
+
-
CH3COO
-
[A ]
pH = pKa + log
[AH]
HCl
-
Cl + H
+
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■
如
何
推
導
公
式
Ka =
logKa =
dissociated
[A-] [H+]
[AH]
associated
[A-]
log [H+]
[AH]
logKa = log [H+] +
[A-]
log
[AH]
-log [H+] = -logKa +
[A-]
log
[AH]
pH = pKa +
[A-]
log [AH]
(1) Ka 的定義
(2) 兩邊取 log
分解右邊 log
(3) 移項
(4) 定義 -log 為 p
Henderson-Hasselbalch equation
How the pKa of a buffer contribute to its buffering effect
How to derive H-H equation from Ka
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■
弱
酸
如
何
作
為
緩
衝
液
分
子
A- + H+
AH
example Acetic acid
CH3COOH = CH3COO- + H+
◎ Ka is the dissociation constant
Ka =
[A-] [H+]
pKa of acetic acid
1
= 10 5
(pKa = 5)
[AH]
★
◎ Ka is derived to get H-H equation
一、兩邊取 log
二、移項取出 [H+]
三、定義 p 為 -log (pH = -log[H+])
H-H
equation
pH = pKa + log
5
5
[A-]
[AH]
dissociated
associated
pH = constant pKa？ ….. when [A-] = [AH], log 1 = 0
Why weak acid could serve as a buffer ?
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■ 弱酸在其 pKa 上下有緩衝作用
functional pH range
pH
Water
pH
pKa
Acetic
acid
5
★
[OH-]
H-H
equation
pH = pKa + log
6
5
Acetic acid has highest buffer effect at its pKa (pH 5)
(just its pKa)
[OH-]
[A-]
[AH]
dissociated
associated
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■ 質子可以吸著或脫離一基團
Proton： The smallest and most abundant particle in the living cell
controlling the pH and the charge property of a molecule
lone pair
electrons
Amino
H+
N H
H+
N H
H
Carboxylic
C
H
O H
O
O
C
O
H+
Ampholyte: A molecule contains both positively and negatively charged groups
Proton can enter or leave a functional group relatively freely
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■ 胺基酸的緩衝作用範圍 Amino acid as a buffer
pH 12
★
9
NH2 H+
6
H- C- R
Isoelectric point =
COO-
3
pK2
★
pK1 + pK2
2
pI
pK1
0
Amino acid can be used as a buffer
[OH] →
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■ 各種常用緩衝液及其使用範圍 Common buffers
Buffer
pH
Formate
Citrate
Acetate
Phosphate
HEPES
Tris
Borate
Carbonate
3.0 - 4.5
3.0 - 6.2
3.7 - 5.5
5.8 - 8.0
6.5 - 8.5
7.1 - 8.9
9.1 - 9.0
9.7 - 10.7
Volatile, could be removed by lyophilization
Universal
2 - 12
Contains several buffers at various pH ranges
Remarks
Bind with divalent metal ions
Volatile, could be removed by lyophilization
Precipitated with Ca; crystallized at low temperature
Low toxicity, used in cell culture
pH effected by temperature; special pH electrode required
Bind with divalent metal ions
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■ 緩衝液使用注意 Notice for two common buffers
Diluted phosphate buffer
raises its pH
Tris is affected by temperature
9
pKa
8
Tris
7
Phosphate
Tris
Phosphate
7
0
8
10 20 30
Temperature
40
0
0.1
0.2
Ionic strength
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■ 緩衝液常用的添加物 Some common additives
Additives
Action
NaN3 (sodium azide)
EDTA
Concentration
Antimicrobials
Remove metal ions
Antioxidant
β-Mercaptoethanol
Dithiothreitol (DTT or DTE) Antioxidant
BSA (bovine serum albumin) Stabilizer
0.01%
0.1 - 1 mM
1 - 10 mM
1 - 5 mM
0.1 - 10 mg/mL
Tween-20, Triton X-100
Glycerol, glucose
PMSF, TPCK, TLCK,
benzamidine etc.
0.5 - 0.05%
50%
Surfactant
Antifreeze
Proteinase inhibitor Trace amount
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■ Beta-mercaptoethanol
α
HOCH2CH2SH
HOCH2CH2SH
+ o
1
2
β
HOCH2CH3
HOCH2CH2S
2
HOCH2CH2S
HOCH2CH2SH
+
H2O
active oxidized form
HOCH2CH2S
Enzyme
SH
X
Enzyme
S
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■ Dithiothreitol (DTT)
CH2SH
HO-C-H
HO-C-H
CH2SH
H-C-OH
HO-C-H
CH2SH
CH2SH
Dithioerythritol
(DTE)
Dithiothreitol
(DTT)
1
2
o2
CH2
H-C-OH S
HO-C-H
S
CH2
Stable cyclic
oxidized form
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■ 緩衝液使用濃度範圍 Concentration ranges
1 mM
10 mM
General buffers
Enzyme assay
100 mM
1M
Protein extraction
Chromatography
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2.3 維持酵素活性 Maintain enzyme activity
● 2.3.1 緩衝液 Buffer
可維持穩定的酸鹼度及離子濃度以保酵素活性
● 2.3.2 試劑的保存 Reagents
試劑要依指示保存在適當的地方
● 2.3.3 酵素活性之維持 Maintain the activity
注意酵素失活的原因有助保持其最高活性
● 2.3.4 酵素活性單位 Enzyme activity unit
Juang RH (2005) EPA
■
試
劑
的
保
存
注
意
事
項
a. Avoid humidity
Open the bottle of a frozen reagent only when its temperature
has been brought back to the room temperature
b. Stored in frozen state
(1) Frequently used reagents should be frozen in aliquot
(2) Avoid repeatedly freezing-thawing
(3) Certain enzymes are very sensitive to freezing L-SP
c. Frozen in glycerol
Protein stored in -20℃ in 50% glycerol
d. Avoid light and microbe
How to store your reagents or enzymes
Mixed well
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■ 細胞內外酵素分佈 Cellular distribution of enzymes
Protein in expressing
Enzymes in the cell
Organelle
Cytosolic
enzymes
Endogenous
organelle enzymes
Imported
enzymes
Secreted
enzymes
Continuous
secreting
Regulatory
secreting
Soluble enzymes
Membrane proteins
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■ 各種酵素的安定性都不同 Enzyme stability
● Reasons enzyme lost its activity:
● Protein Denatured
● Active site destroyed
● Protease proteolysis
● Enzyme Inhibitor
■ Physical denaturation
Physical/chemical denaturation
Chemical reaction
Inactivated by degradation
Natural or synthetic inhibitors
Heating, freezing, foaming, adsorbing
■ Chemical denaturation Extreme pH, oxidation, heavy metals
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■ 蛋白脢的專一性及其抑制劑 Protease families
Family
Example
CarboxyMetal
Protease peptidase A
Serine Chymotrypsin
Trypsin
Protease
Mechanism
Zn
2+
E72 H69
H196
S195-OH57
D102
C25-S-
Cysteine
Protease
Papain
H195
Aspartyl
Protease
Pepsin
Renin
D215
H2O
D32
Specificity Inhibitor
Nonpolar
EDTA
EGTA
Aromatic
Basic
DFP
TLCK
TPCK
Nonspecific
PCMB
Leupeptin
Nonspecific
Pepstatin
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