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A.C COLLEGE OF TECHNOLOGY
ANNA UNIVERSITY, CHENNAI-600025.
BIOPROCESS LAB RECORD
NAME : ROLL NO : DEPARTMENT : IBT
BONAFIDE CERTIFICATE
A.C.COLLEGE OF TECHNOLOGYNAME :
BRANCH :
ROLL NO. :
This is to certify that _____________________________________
of _____________________________________
has completed the BIOPROCESS LAB-I (IB9306) in the year 2011-2012
Submitted for the practical examination conducted on ________________________
INTERNAL EXAMINER EXTERNAL EXAMINER
INDEX
S NO DATE TOPIC
1
2
3
4
5
6
7
8
9
10
11
12
Exp No:
Date :
STUDY OF ENZYME KINETICS OF INVERTASE
Aim: To determine the enzyme kinetic parameters Vmax, Km and kcat of the enzyme invertase.
Theory: The hydrolysis ('inversion') of sucrose, completely or partially, to glucose and fructose provides sweet syrups that are more stable than pure sucrose syrups. Sucrose is α-D-glucopyranosyl (1,2)-β-D-fructofuranoside and can therefore be hydrolysed both by α-glucosidases and β-fructofuranosidases. Invertase is a β-fructofuranosidase that hydrolyses sucrose as well as other b-fructans such as raffinose.
Yeast (Saccharomyces cerevisiae) invertase is essentially an intracellular enzyme and disruption of cell membranes is necessary for its extraction. A crude extract prepared by autolysis of dried baker's yeast gives satisfactory activity with no interfering activities. This practical exercise demonstrates how the kinetic parameters Km and Vmax may be determined for this industrially important enzyme. The kinetic parameters are studied by plotting the Michaelis-Menten curve and Lineweaver Burke Plot.
The Michaelis Menten equation relating reaction rate and concentration of substrate is given by
Lineweaver-Burke equation is given by
Materials required:
Invertase : 1 ml stock is diluted with 100ml phosphate buffer
Sucrose solution 50 mM
Phosphate Buffer (pH= 7.0,Potassium) 0.05M
Procedure:
1. Sucrose was taken in increasing volumes of 0, 0.5, 1.0, 1.5, 2.0, 2.5& 3.0ml in different test tubes.
2. The volume was made upto 3ml using phosphate buffer (pH= 7.0).3. 200 µl of invertase is added was added to the test tubes and incubated for 20 minutes at
room temperature.4. The reaction mixture is boiled at 90 C for 5 minutes to stop the reaction.5 The velocity of the product formation, the glucose was analysed by using GOD- POD kit by taking 1.8 ml GOD POD reagent and 0.2 ml of the reaction mixture and read at 540 nm.
The readings are tabulated and the kinetic parameters are calculated.
Table 1: Standard values of glucose
Glucose stock 0.2 mg/ml
Glucose Absorbance
Volume
µl
Quantity
µg
OD @ 540 nm
20
40
60
80
100
4
8
12
16
20
Table 2: Tabular column for the calculation of velocity of the reaction for various substrate concentration
S.no
sucrose
1/S
glucose
1/V
Vol of
Sucrose
(ml)
Molarity of
Sucrose in 3ml (S)
mM
OD @
540 nm
Conc. of glucose
g/l mM
Velocity of reaction (V)
mM/min
Graphs to be plotted:
1. Michaelis Menten plot (V vs. S).2. Lineweaver Burk plot (1/V vs. 1/S).
Results and Inferences:
Exp. No:Date:
EFFECT OF TEMPERATURE ON ENZYME ACTIVITY
Aim: 1. To study the effect of change in temperature on enzyme activity and calculate Ea
and A.
Theory:
The temperture of a system is to some extent a measure of the kinetic energy of the molecules in the system. Increases in the temperature of a system results from increases in the kinetic energy of the system. This has several effects on the rates of reactions.
1) More energetic collisions2) The number of collisions per unit time will increase.3) The heat of the molecules in the system will increase.
Given the above considerations, each enzyme has a temperatuare range in which a maximal rate of reaction is achieved. This maximum is known as the temperature optimum of the enzyme. Invertase (systematic name: beta-fructofuranosidase) is an enzyme that catalyze the hydrolysis (breakdown) of sucrose. Invertase, usually derived from yeast, has an Optimum temperature of 50°C and an optimum pH of 4.5. A further increase in temperature will cause the activity to decline, and with further increase in temperature the activity will drop to nil. It is because at higher temperature the 3-D structure of the enzyme is destabilized and may even collapse resulting in its total denaturation. When the 3-D structure of the enzyme is destabilized the geometry of the active site is also affected resulting in slowing down and even total abolition of catalytic activity.
Materials required:
Invertase prepared by sonication (French press) of Baker’s yeast solution (1% suspended in phosphate buffer of pH 7 is the stock solution.
Invertase : 1 ml stock is diluted with 100ml phosphate buffer
Sucrose solution: 50 mM
0.05M Phosphate buffer at pH of 7.0
Procedure:
Take 5 labelled test tubes. 3ml of 50 mM sucrose solution was added to each of the tubes. 200 μl of the invertase solution of was added to each of the test tubes, excluding the
blank.
Incubated the test tubes for20 minutes, one each at different temperatures -- 30°C, 40°C, 50°C and 70°C.
The reaction was stopped by heating the test tubes for 5 min in a water bath kept at 90°C. Glucose, the product formed was analysed using the GOD-POD kit. The readings were tabulated and Vmax is calculated.
Observation:
Table 1: Standard values of glucose
Glucose stock: 0.2 mg/ml
Glucose AbsorbanceVolume
µlQuantity
µgOD at 540 nm
Table 2: Tabular column for the Effect of Temperature on Enzyme Kinetics
Amount of Sucrose (ml)
Amount of Phosphate Buffer (ml)
Amount of enzyme (µl)
Temperature of incubation (oC) for
20 mins
Absorbance at 540nm
Table 3: Tabular column for the Velocity of Reaction
Concentration of Glucose
(g/ml)
Velocity of Reaction (V)
mM/min (x10-3)
Temperature (oC)
Table 4: Tabular column for the Arrhenius Relations
Temperature (oC)
1/T Velocity (x10-3)
K ln K
Graphs to be plotted:1. Temperature profile for Invertase (Vmax vs. Temperature)
2. Plot graph of lnK vs. 1/T and calculate Ea and A.
Result:
Exp No:
Date :
EFFECT OF PH ON ENZYME KINETICS
Aim: To study the effect of change in pH on invertase activity.
Theory:
Enzymes have ionic group in the active site and these groups must be in a suitable form (acid or base)n to function. Variation in pH of the medium results in changes in the ionic form of the active sites and changes in the activity of the enzyme and also in the reaction rate. Changes in pH may also alter the 3D shape of the enzyme. For this reason, enzyme is active in a certain pH range. The pH may affect the maximum reaction rate and stability of enzyme. If the substrate contains ionic group, then pH of the medium affects the affinity of substrate to enzyme. At extreme pH tertiary structure of protein may be disrupted and protein may be denatured. At moderate pH values, tertiary structure is not disrupted. Change in pH affects shape and active site of enzyme, so substrate binding is hindered and affects process catalysis.
Materials required:
Invertase prepared by sonication (French press) of Bakers yeast solution (1% suspended in acetate/phosphate buffer of appropriate pH - 4, 5, 6, 7, 8) is the stock solution.
Invertase : 1 ml stock is diluted with 100ml of appropriate buffer
Sucrose solution 50 mM made in buffer of appropriate pH (4, 5, 6, 7, 8)
Buffers of pH 4, 5, 6, 7, 8 prepared using appropriate buffers of 0.05M.
Procedure:
1. Take 6 labelled test tubes2. 3ml of 50 mM sucrose solution of varying pH (4 to 8) was added to each of the 5 tubes.
To one test tube (Blank), add 50 mM sucrose of pH 7.
3. 200 μl of the invertase solution of appropriate pH was added to each of the test tubes, excluding the blank.
4. Incubated for 20 minutes at room temperature.5. The reaction was stopped by boiling the test tubes for 5 min in a water bath.6. Glucose, the product formed was analysed using the GOD-POD kit.
Observation:
Table 1: Standard values for glucose concentration
Stock:
Table 2: Tabular column for the calculation of Vmax
S.no pH OD @ 540 nm Vmax
Graphs to be plotted:
pH profile for invertase (Vmax vs. pH)
Result:
Amount of glucose (mg/ml)
OD @ 540 nm
Exp no:Date:
Enzyme Inhibition Kinetics
Aim: To study the inhibition kinetics of CuSO4 on Enzyme Invertase.
Theory:Inhibitors are substances which tend to decrease the rate of an enzyme catalyzed reaction. Reversible inhibitors bind to an enzyme in a reversible fashion and can be removed by dialysis whereas irreversible inhibitors cannot be removed. There are different types of reversible inhibitors:
i) Competitive inhibitors: These inhibitors closely resemble the substrates whose reactions they inhibit. They compete for and bind to the same active site on the enzyme forming a dead end [SI] complex.
ii) Uncompetitive inhibitors: These inhibitors bind to the enzyme substrate complex and not to the free enzyme. [ESI] is formed which is a dead end complex.
iii) Mixed inhibitors: These inhibitors bind to either the substrate binding site or the enzyme-substrate complex, thereby, inhibiting product formation.
Materials Required:
Invertase prepared by sonication (French press) of Baker’s yeast solution (1% suspended in citrate buffer of pH 4.5 is the stock solution.
Invertase: 1 ml stock is diluted with 100ml citrate buffer
Sucrose solution: 50 mM
0.05M citrate buffer at pH of 4.5
Procedure:
Sucrose solution was taken in increasing volumes of 0.5, 1, 1.5, 2.0, 2.5 and 3ml in different test tubes and is done in duplicates. Volume is made upto 3 ml in the test tubes with the buffer
300 µl of 0.1 M CuSO4 solution was added to one set and to the other 300µl of buffer was added.
The reaction was started by adding 200 μl invertase to each test tube. The reaction mixture was incubated for 20 minutes at room temperature. The reaction was stopped by boiling the tubes for 5 minutes. Glucose, the product formed was estimated using the GOD-POD kit. The readings were tabulated.
Observation:
Table 1: Standard values of glucose
Glucose stock: 0.2 mg/ml
Glucose AbsorbanceVolume
µlQuantity
µgOD @ 540 nm
Table 2: Tabular column for the Enzyme activity with inhibitor
Amount of Sucrose (ml)
Amount of Phosphate buffer (ml)
Amount of 0.1M CuSO4
(µl)
Amount of Enzyme (µl)
OD at 540nm
Table 3: Tabular column for the Line-weaver Burke graph for reaction with inhibitor
[S]mM
[P]mM
Tine(min)
Velocity (V) mM/min
(x10-3)
1/[S]mM-1
1/[V]mM-1
Table 4: Tabular column for the Enzyme activity data without Inhibitor
Amount of Sucrose (ml)
Amount of Phosphate buffer (ml)
Amount of Enzyme (µl)
OD at 540nm
Table 5: Tabular column for the Line-weaver Burke graph for reaction without inhibitor
[S]mM
[P]mM
Tine(min)
Velocity (V) mM/min
(x10-3)
1/[S]mM-1
1/[V]mM-1
Graphs to be plotted:
1. Lineweaver- Burk plot (1/[S] vs 1/[V]).2. Vmax vs. [I].
Result:
Exp. No:
Date:
STUDY OF DEACTIVATION KINETICS OF ENZYME INVERTASE
Aim: To study the deactivation kinetics of Invertase enzyme.
Theory:The rate of enzyme catalyzed reaction increases with temperature upto a certain limit. Above a certain temperature, the enzyme activity decreases with temperature due to enzyme denaturation. The kinetics of Thermal denaturation can be expressed as,
Where Kd is the deactivation constant. Kd varies with temperature according to the Arrhenius equation,
Where Ed is the deactivation energy and varies between 40-130 kcal/gmol
Procedure:
200 µl of Invertase in 4 test tubes/eppendorfs was heated and maintained at 65°C for 5, 10, 15 & 20 minutes.
It was then brought to room temperature and 3ml of 50mM sucrose solution was added to it and reaction was allowed to proceed for 20 minutes.
In a separate test tube used as control, invertase not subjected to heat treatment was allowed to react with sucrose for 20 minutes at room temperature.
Reactions in all the test tubes are stopped by boiling in a water bath for 5 minutes.
Glucose concentration was analyzed using GOD-POD kit.Observation:Table 1:
Glucose AbsorbanceVolume
µlQuantity
µgOD at 540 nm
Table 2: Details of heating time (deactivation kinetics)
Sl. No. Amount of
Invertase
Time at 65oC (min)
Amount of Sucrose
(ml)
Absorbance at 540nm
[P] mM Velocity of reaction
(mM/min)
Vmax = Kcat*E0 at time 0 min and Vmax = Kcat*Eact at time 5, 10, 15, and 20 minutes.
Table 3: Activation Energy values
Eactivation lnE
Graphs to be plotted:
1. Plot Eactive vs. time and calculate kd.
Inference and Result
Exp. No:
Date:
Kinetics of enzyme Immobilization
Aim: To study the effect of immobilization of Invertase in calcium alginate beads and compare with the unimmobilized enzyme kinetics.
Theory: An immobilized enzyme is an enzyme that is attached to an inert, insoluble material such as calcium alginate (produced by reacting a mixture of sodium alginate solution and enzyme solution with calcium chloride). This can provide increased resistance to changes in conditions such as pH or temperature. It also allows enzymes to be held in place throughout the reaction, following which they are easily
separated from the products and may be used again. It is recognized that the kinetic constants measured with immobilized enzymes are not true kinetic constants equivalent to those obtained in
homogeneous reactions. They are apparent values because of the effects of diffusion and partitioning. There is usually a decrease in specific activity of an enzyme upon immobilization, and this can be attributed to denaturation of the enzymatic protein caused by the coupling process. Once an enzyme has been immobilized, however, it finds itself in a micro environment that may be drastically different from that existing in free solution.
Materials Required:
Sucrose: 50mM
Invertase: Invertase prepared by sonication of 1% Baker’s yeast in Phosphate buffer pH 7 and is the stock solution.
1 ml of stock solution is diluted to 100 ml of buffer which is the invertase solution
Sodium alginate: 1g in 100ml of invertase solution
6% (w/v) CaCl2 solution is prepared.
Procedure:Preparation of Immobilized enzyme:
This viscous solution of 1% sodium alginate in Invertase solution was made to fall in drops into a 6% CaCl2 solution using a peristaltic pump or syringe, to form the beads.
A known number of beads were taken and reaction was carried out in 50ml sucrose solution.
Beads were incubated for 20 minutes. Glucose concentration was estimated using GOD/POD kit.
Determination of void volume and bead size:
Beads were taken up to a certain height in the measuring jar. All voids were emptied i.e. the CaCl2 solution was decanted off.
Water was then added to the same height. Water was decanted into another measuring jar and this volume is the void volume, Vv. Volume occupied by beads = Vtot – Vv
The number if beads was counted = N Volume of each bead Vb = 4/3 rb³ The radius of the bead is thus determined.
Unimmobilized system.
From the number of beads taken for the experiment and the calculated value of radius of bead, the total amount of enzyme in the immobilized system was known.
The same amount of enzyme was taken from the lysed yeast cells and free enzyme kinetics under identical conditions (as for immobilized kinetics) was carried out.
Observation:
Table1: Immobilized system
No of beads
N
Amount of Invertase in the
beads (g)
OD at 20min
Concentration of Glucose g/l/M
(x10-3)
V (amount of glucose formed)
g/l min mM /min
Table2: Unimmobilized system.
Amount of enzyme in the immobilized beadsml g
OD at 20min
Concentration of Glucose g/l/M (x10-3)
Velocity g/l /min mM/min
(x10-4) (x10-2)
Result:The velocities calculated are as follows:Vimmobilized =Vunimmobilized =Exp. No:Date:
STUDY OF GROWTH KINETICS IN SHAKE FLASK CULTURE
Aim: To study the growth pattern of E. coli in batch culture using shake flask. To determine the maximum specific growth rate during log phase and apparent biomass yield coefficient.
Theory :The growth curve of an E. coli culture can be divided into distinct phasesLag phase occurs after dilution of the starter culture into fresh medium.Cell division is slow as the bacteria adapt to the fresh medium. After 4–5 hoursthe culture enters logarithmic (log) phase, where bacteria grow exponentially.Cells enter stationary phase (~16 hours) when the available nutrients are used up.The cell density remains constant in this phase. Eventually the culture enters the Phase of decline, where cells start to lyse, the number of viable bacteria falls, and DNA becomes partly degraded
Materials requiredStrain Used: E. coli DH5α
Medium Used: glucose 5 g/l
yeast extract 5 g/lNH4Cl 1 g/lK2HPO4 5 g/lKH2PO4 3 g/lNaCl 0.5 g/l
1M MgSO4.7H2O 0.5 g/l trace elements 1 ml/l
Trace elements composition:
FeSO4 50 mg/lAl2(SO4)3 10mg/lCuSO4 2mg/lH3BO3 1mg/lMnCl2 20mg/lNiCl2 1mg/lNa2MoO4 50mg/lZnSO4 5mg/l
Medium is prepared by autoclaving the following medium components separately and added to 250 ml shake flask to make 50 ml of medium under sterile conditions in the Laminar flow hood.1. glucose 2. yeast extract with other salts mentioned above
3. magnesium sulphate4. Trace metals
Paramaters to be measured:
a. OD at 600nm.b. Dry weight using pre-weighed eppendorf tubesb. Residual glucose analysis of the supernatant
Procedure:
50 ml of medium was prepared in 250ml shake flask.
500µl of inoculum from an overnight culture grown in Luria Bertani medium was added to the shake flask.
Incubation was done in shaker at 37°C and 200 rpm.
Every hour, 1ml of culture was taken for measuring O.D at 600 nm with medium as blank. Another 1 ml of culture was withdrawn from the shake flask and centrifuged at 10,000 rpm for 5min at 4°C.
The pellet and supernatant were stored at -20°C in the freezer for further analysis.
For dry weight analysis, the pellets of last three hour sample were taken for analysis. The pellet stored in pre-weighed eppendorf tubes were washed by re-suspending in 1 ml
of 0.8% saline and centrifuged at 10,000 rpm for 5min at 4°C.
The pellet was dried at 90°C in oven for 20-24 hours. After removing from the oven, the eppendorf tubes containing the dried pellet was cooled in a dessicator and weighed.
Residual glucose analysis was done by using the GOD-POD kit .The test can be performed either using cuvette in a spectrophotometer or in a 96 well plate reader.
For measuring glucose standard, 2 to 10 µg of glucose for 200 µl of reaction mixture was taken using stock solution of 1mg/ml. And 10 to 100 µg of glucose for 1000 µl of reaction mixture.
Assay was done as per protocol given in the kit. The sample is incubated at room temperature for 30 min.
Absorbance were measured at 492 nm against buffer prepared using the kit as blank. Values were computed using standard graph.
Formulae used
1. µ = ln OD2 – ln OD1
t2 – t1
Where µ = specific growth rate (1/h) t = time at which the OD was measured in (h)
2. Y X/S = X2 – X1
S2 – S1
Where Y X/S = measured biomass yield coefficient with respect to glucose X = biomass in (g/l) S = residual glucose concentration in (g/l)
Table 1.0
Glucose AbsorbanceVolume
µlQuantity
µgOD at 540 nm
Table 2.0
Sl. No. Time (hour) OD (600nm) ln OD µ (specific growth rate)
1/hr
Graphs to be plotted
OD vs timeln OD vs timeOD vs dry weightOD at 492nm vs standard glucose (µg of glucose )
Inferences and Result
Exp. No:Date:
PLACKETT BURMAN DESIGN OF MEDIA OPTIMISATION
Aim: To determine the combination of independent variables at appropriate levels so as to achieve maximum specific growth rate.
Theory:Plackett Burman is the design for optimising multifactorial experiments. It is used in screening multicomponents at two levels. It will give the range at which you have to optimize the experiment further. But this design will not give optimum concentration of the variable. It is useful for more than five variables. Here n no. of experiments will be conducted for n-1 variables. Where n is the multiples of 4 like 8,12,16,20,….100. Dummy variables are used in this process to estimate the experimental error and they have no influence in the process. Minimum one or two dummy variables should be included in the experimental set. More can be included if the real variables are less.
Materials and Methods
Strain used: E. coli DH5α
Medium used
Sl.No Medium High Low
g/l g/l1 glucose 4 0.5
2 yeast extract 1 0
3 Cas aminoacid 0.5 0
4 Ammonium Chloride 2 0.5
5 Sodium Phosphate 3 3
6 Glycine 1 0
7 Magnesium Sulphate 0.5 0.5
Stock Concentration of Media components.
Medium Concentration (g/l)Glucose 200Yeast extract 100Cas amino acid 50NH4Cl 100Glycine 100MgSO4.7H2O 100Prepare all the stock solution in 3g/l of phosphate buffer.Quantity of stock solution to be added to make up 20 ml of medium.
Trial glucose Yeast ext
Casa. acid
Amm.chl. phos. Glycine Mag.sul. Vol.*
µl µl µl µl µl µl µl1 400 200 200 100 - 0 50 9502 50 200 200 400 - 200 50 11003 50 0 200 400 - 0 50 7004 400 0 0 400 - 200 50 10505 50 200 0 100 - 200 50 6006 400 0 200 100 - 200 50 9507 400 200 0 400 - 0 50 10508 50 0 0 100 - 0 50 200
Vol* is the volume of phosphate buffer to be removed from the shake flask before addition of stock solution of media components.
Table 3:
Trial glucose Yeast Casa. acid
Amm.chl. phos. Glycine Mag.sul. Vol
1 H H H L H L H 2 L H H H L H L 3 L L H H H L H 4 H L L H H H L 5 L H L L H H H 6 H L H L L H H 7 H H L H L L L 8 L L L L L L L
Procedure:
20 ml of medium was prepared in 100ml shake flask Medium is prepared by autoclaving 3 g/l of sodium phosphate buffer at pH of 7.0 and the remaining components of the medium were sterilized separately and added to make up 20 ml of medium in 100 ml shake flask.
1000µl of inoculum from an overnight culture grown in Luria Bertani medium was added to the shake flask.
Incubation was done in shaker at 37°C and 200 rpm.
Every hour, 1ml of culture was taken for measuring O.D at 600 nm with medium as blank.
Observation:Table 4:
Glu Yeast CAS NH4Cl. Phos Gly MgSO4
∑A(H)
∑A(L)
Effect
Mean Sq.
Exp. Error
F-test
Table 5:
S.No Time OD LnOD µ
1/hr
Formulae used
µ = ln OD2 – ln OD1
t2 – t1
Where µ = specific growth rate (1/h) t = time at which the OD was measured in (h)
Effect on each component: [∑ A(H) - ∑ A (L)]
4
Mean square: [∑ A(H) - ∑ A (L)]2
8
Experimental error = [mean square of phosphate + mean square of MgSO4 ]
2
F- test = Mean square
Experimental error
Graphs to be plotted
OD vs timeln OD vs time
Inference and Result
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