In this experiment concerning the activity of enzymes we tested the different effects of various concentrations, pH, Temperature, and Inhibitors over intervals of time. For the effects of concentration of enzyme extract, or peroxidase we mixed six of seven tubes to get three different concentrations of extract. By doing this we wanted to know whether the concentration would positively or negatively affect the activity of the enzyme, in which we predicted that the concentration would increase the activity. The three extract concentrations being 0.5ml from the mixing of tubes 2 and 3, 1.0ml from tube 4 and 5, and 2.00ml from 6 and 7, while the first tube of the seven that wasn’t mixed was the control containing zero extract. The control and the mixed tubes together made 8ml, and was poured into cubettes to be placed in the spectrometer at an absorbance of 500nm. …show more content…
However looking at figure 1 the gray line of the graph pertaining to the concentration of tubes 6 and 7, there was a drop in activity visually on the graph due to an outlier of class data. Yet, looking at figure 2 the reaction rate of looking at the reaction rate or rate of change in the absorbance over the time of two minutes in 20 second increments. The slopes of all three lines show that the peroxidase looks directly proportional in data. Thus, supporting our hypothesis that the concentrations of peroxidase will increase the absorbance of the enzyme and not denature it because factors such as temperature, or pH were not
In this experiment, the naturally occurring peroxidase is extracted from homogenized turnip (Brassica rapa) pulp (Coleman 2016). Its role in the environment is to remove toxic hydrogen peroxide during metabolic processes where oxygen is used (Coleman 2016). The goal of this experiment is to evaluate the change of absorbency of turnip peroxidase within a metabolic reaction utilizing oxygen. Any change noted is indicative of the peroxidase removing hydrogen peroxide. Within this experiment, the extract will be prepared, the amount of enzyme will be standardized, and the effect of changing the optimal conditions will be observed. If the enzyme concentration is increased then the rate of the reaction decrease. If the pH of solutions used is increased
The preparation for the experiment started by gathering the solutions of enzyme Peroxidase, substrate hydrogen peroxide, the indicator guaiacol and distilled water. Two small spectrometer tubes and three large test tubes with numbered labels. In addition, one test tube rack, one pipet pump and a box of kimwipes were also gathered. Before the experiment, the spectrometer must be set up to use by flipping the power switch to on. Following, the machine was warmed up for 10 minutes and the filter lever was moved to the left. In addition, I set the wavelength to 500 nm with the wavelength control knob. Before the experiment, I had to create the blank solution by pipetting 0.1 ml of guaiacol, 1.0 ml of turnip extract and 8.9 ml water into tube #1. Following the creation of the blank, a control 2% solution was created.
In this lab or experiment, the aim was to determine the following factors of enzymes: (1) the effects of enzymes concentration the catalytic rate or the rate of the reaction, (2) the effects of pH on a particular enzyme, an enzyme known and referred throughout this experiment as ALP (alkaline phosphate enzyme) and lastly (3) the effects of various temperatures on the reaction or catalytic rate. Throughout the experiment 8 separate cuvettes and tubes are mixed with various solutions (labeled as tables 1,3 & 4 in the apparatus/materials sections of the lab) and tested for the effects of the factors mentioned above (concentration, pH and temperature). The tubes labeled 1-4 are tested for pH with pH paper and by spectrophotometer, cuvettes 1a-4a was tested for concentration and cuvettes labeled 1b-4b was tested for temperature in four different atmospheric conditions (4ºC, 23ºC, 32ºC and 60ºC) to see how the enzyme solution was affected by the various conditions. After carrying out the procedures the results showed that the experiment followed the theory for the most part, which is that all the factors work best at its optimum level. So, the optimum pH that the enzymes reacted at was a pH of 7 (neutral), the optimum temperature that the reactions occurs with the enzymes is a temperature of 4ºC or
Five cuvettes provided by the instructor were used during the experiment. The transmittance on the spectrophotometer was zeroed on an empty chamber and it was set at a wavelength of 486 nm. There was only one blank containing 0.5 mL of enzyme solution (catechol oxidase) and 4.5 mL of pH 6 buffer. The blank was prepared at the beginning of the experiment and used throughout the experiment. The blank was used to zero the absorbance on the spectrophotometer before each experimental trial. The experimental cuvettes contained 0.5 mL of catechol oxidase (enzyme), 0.5 mL of 5mM catechol (substrate), and 4.0 mL of pH 6 buffer for a total of 5.0 mL of solution. The results for the experimental trials were obtained after 0 seconds, 30 seconds, 1minute and 30 seconds, 3 minutes, and 5 minutes in five different reactions. The enzyme and substrate were obtained using a micropipette, and the pH was measured using a 10mL pipet. Each experimental trial was carried out twice for a total of ten experimental
This experiment looked at how substrate concentration can affect enzyme activity. In this case the substrate was hydrogen peroxide and the enzyme was catalase. Pieces of meat providing the catalase were added to increasing concentrations of hydrogen peroxide in order to measure the effect of hydrogen peroxide concentrations on the enzyme’s activity. The variable measured was oxygen produced, as water would be too difficult to measure with basic equipment.
In the experiment we used Turnip, Hydrogen Peroxide, Distilled Water, and Guaiacol as my substances. On the first activity, Effect of Enzyme concentration of Reaction Rate for low enzyme concentration, we tested three concentrations of the turnip extract, and hydrogen peroxide. For the Turnip Extract I used 0.5 ml, 1.0 ml, and 2.0 ml. For hydrogen peroxide we used 0.1 ml, 0.2 ml, and 0.4 ml. We used a control to see the standard, and used a control for each enzyme concentration used. The control contains turnip extract and the color reagent, Guaiacol. We prepared my substrate tubes separately from the enzyme tubes. My substrate tube
The data in proves that our hypothesis was correct. When we increased the temperature to 35°C, the the enzyme activity increased because kinetic energy increased, increasing the collisions between the substrate and the enzyme, and thus creating a higher chance of reaction. When we increased the temperature to 45°C, the enzyme activity decreased as the enzyme became denatured,because the atoms in the enzyme had enough energy to overcome the hydrogen bonds between the R groups that give the enzyme its shape From our data, we could conclude that the optimal temperature of turnip peroxidase is around 35°C and around 45°C, it will start to denature.
Figure one depicts the reaction rate of peroxidase enzyme over time. The y-axis shows the absorbance of the assay solutions, and the x-axis depicts time it took for the reaction to occur in seconds.
The effectiveness of peroxidase was measured in a varying pH environment. The environment’s pH can range from 1-14, 7 being neutral, 7-1 being more and more acidic towards 1, and 8-14 being more and more basic towards 14 (Raven, 2011).
An Enzyme is a protein, which is capable of starting a chemical reaction, which involves the formation or breakage of chemical bonds. A substrate is the surface or material on or from which an organism lives, grows, or obtains its nourishment. In this case it is hydrogen peroxide. This lab report will be explaining the experiment held to understand the effects of the changes in the amount of substrate on the enzyme’s reaction.
In this laboratory exercise, studies of enzyme catalase, which accelerates the breakdown of hydrogen peroxide into water and oxygen. The purpose was to isolate catalase from starch and measure the rate of activity under different conditions. The laboratory was also conducted in association with a second laboratory that measured the effects of an inhibitor on the enzymes.
The purpose of this experiment is to learn the effects of a certain enzyme (Peroxidase) concentration, to figure out the temperature and pH effects on Peroxidase activity and the effect of an inhibitor. The procedure includes using pH5, H202, Enzyme Extract, and Guaiacol and calibrating a spectrophotometer to determine the effect of enzyme concentration. As the experiment continues, the same reagents are used with the spectrophotometer to determine the temperature and pH effects on Peroxidase activity. Lastly, to determine the effect of an inhibitor on Peroxidase, an inhibitor is added to the extract. It was found that an increase in enzyme concentration also caused an increase in the reaction rate. The reaction rate of peroxidase increases at 40oC. Peroxidase performed the best under pH5 and declined as it became more basic. The inhibitor (Hydroxy-lamine) caused a decline in the reaction rate. The significance of this experiment is to find the optimal living conditions for Peroxidase. This enzyme is vital because it gets rid of hydrogen peroxide, which is toxic to living environments.
Turnips and horse radish roots are rich source of this enzyme. In this experiment, we would carry out a reaction between hydrogen peroxide and guaiacol which is colorless dye, using peroxidase as a catalyst, to produce water and an oxidized form of guaiacol which is brown. The formation of brown color would serve as an indicator that the breakdown of Hydrogen Peroxide took place. The enzyme activity would be directly proportional to the brown color intensity. The color intensity would be measured using a spectrophotometer and standardized to find the corresponding concentration for each absorbance unit.
Abstract: Enzymes, catalytic proteins that at as catalysis which makes the process of chemical reactions more easily. There are two main factors that actually affects enzymes and their functions which are temperature and pH. Throughout this experiment, the study how pH and peroxidase affects each other and the enzyme was made. The recordings of how the enzymes responded when it was exposed to four different pH levels to come up with an optimum pH which was predicted in the hypothesis and the IRV at the end.
Enzymes are macromolecules that act as a catalyst, and it’s a chemical agent that accelerates the reaction without being consumed by the feedback or the results (Campbell and Reece, 2005). After the adjustment by the enzymes, the chemical movement through the pathways of metabolism will become awfully crowded because many chemical reactions are taking a long time (Campbell and Reece, 2005). There are two kinds of reactions in nature. The first one is Catabolic reaction and the second one is Anabolic reaction. Catabolic reactions are large molecules that are broken up into smaller molecules (Ahmed, 2013). Anabolic reactions are small molecules that join to make larger molecules, like polymerization (Ahmed, 2013). If you