Introduction: Enzymes are biological catalysts that increase the rate of a reaction without being chemically changed. Enzymes are globular proteins that contain an active site. A specific substrate binds to the active site of the enzyme chemically and structurally (4). Enzymes also increase the rate of a reaction by decreasing the activation energy for that reaction which is the minimum energy required for the reaction to take place (3). Multiple factors affect the activity of an enzyme (1). These factors include the pH and the temperature of the solution (1). Most enzymes have a preferred temperature and pH range (2). The preferred temperature for catalase falls between the ranges of thirty five to fifty degrees Celsius (4). Temperatures that are too high denature the enzyme and halt the enzyme’s activity (2). Catalase denatures starts to denature at fifty five degrees Celsius (2). Reactions in the human body produce hydrogen peroxide as a product (1). Since hydrogen peroxide is poisonous to the human body, catalase catalyzes hydrogen peroxide into water and oxygen (2 H2O2 → 2 H2O + O2) (1). According to the collision theory, a reaction can only occur if particles collide with sufficient energy to overcome the activation energy and with correct geometrical orientation (3). Increasing temperature increases the kinetic energy of the particles which means that an increase in temperature will increase the speed of the hydrogen peroxide and the catalase molecules which
We also tested to see if Peroxidase was able to recover its catalytic ability after being exposed to sub optimal temperatures. After being brought to optimal temperatures the solutions were still able to react,
Because of the fact that reactions are catalyzed by enzymes when they randomly collide with substrate molecules, increasing the temperature would increase the reaction rate. Increasing the temperature further increases the vibrational energy of the enzyme molecules, straining the bonds that keep them together. Furthermore, when the temperature is higher, more bonds will break because of these strains, causing the active site of the enzymes to change too. Similar to pH, a change in the shape of the active site leads to the substrate not being able to fit perfectly, leading to the enzyme not being able to catalyze the reaction. Overall, an increase in temperature will cause the rate of reaction to increase initially due to the increased kinetic energy.
Catalase Activity on Substrate Based On Gas Pressure Production Rate Name of the Class Author’s Name Date Enzymes are organic compounds which act as catalysts and speed up biological reactions in biological organisms. They are not destroyed or changed during the reaction but rather they are used over and over again to catalyze many more reactions. Their activity may be affected and altered by factors such as temperature, substrate concentration, enzyme concentration and Ph.
(Enzymes par. 1) They are very sensitive to their surroundings and highly reactive to the pH levels and temperature once exposed to either one. Temperature causes damage to the enzyme,
Introduction Chemical reactions are seen in many instances, including those in which one substance is being converted to another. Natural chemical reactions will occur without intervention, however they occur slowly. Enzymes become important in these situations. Enzymes are proteins that act in cells to ensure reactions occur at appropriate speeds. In other words, they act as catalysts.
It was expected that an extreme temperature would decrease the rate of reaction and results observed support that idea. With reference to figure 1, the peak performance of catalase was at 30℃, which was the closest to its usual environment
1. What temperature will have the fastest reaction if a catalase enzyme and hydrogen peroxide are mixed together? 2. If catalase enzymes and hydrogen peroxide are mixed together, then the fastest reaction will occur when the test tube is placed in a 30 degrees C water bath because that is the temperature when and hydrogen peroxide react the fastest. 3.
The fungal amylase showed the highest enzyme activity was at this temperature, with the lightest color from all the temperatures. Thus the individual group data, showed bacterial amylase to have an optimal temperature at 0°C, and fungal amylase showed to have an optimal temperature at 55°C. Nevertheless, the class data does not support these findings by the individual group. Base on the class data, both bacterial amylase and fungal amylase have an optimal temperature of 55°C, proving the hypothesis. This difference between the class data and the individual data shows that errors must have occurred while preforming the bacterial enzyme
The objective of this lab was to determine the best pH level to increase enzyme activity. As this objective was met, it was discovered that water (pH level 7) was the best for percent absorbance. The hypothesis for this experiment was, “If peroxidase is an enzyme and therefore contains certain pH tolerances, then when placed in solution with pH levels of three, seven, and ten and the reaction is measured by a colorimeter, then water will be the optimal solution for maximum reaction rate.” As seen in the tables and graphs, the data supported the hypothesis due to the fact that most enzymes have an optimal pH of 4-9.
A simple change in temperature, a molecule out of place, and a sudden change in the pH level are just some of the things that can harm an enzyme 's reaction rate (the speed at which a chemical reaction proceeds) (5). To test the reaction rate of an enzyme, a lab was done to simulate what would happen to an enzyme under extreme conditions. The enzyme (represented by a hand) had to catalyze as many substrates as possible (represented by toothpicks) within 60 seconds. The experiment dealt with environmental factors such as extreme cold, presence of other molecules, etc. The lab that was simulated directly correlated to many of the topics discussed in class, like explaining the importance of enzymes and measuring the enzymes’ ability to function under different conditions.
The effect of pH on the speed of enzyme interaction with substrate chemicals Hypothesis: About pH: If the pH level is less than 5, then the speed of the enzyme reaction will be slower. About temperature: If the temperature stays the same, then the speed of the enzyme reaction will not be completely affected. Background information: The function of enzymes is to speed up the biochemical reaction by lowering the activation energy, they do this by colliding with the substrate.
Enzymes speed up chemical reactions enabling more products to be formed within a shorter span of time. Enzymes are fragile and easily disrupted by heat or other mild treatment. Studying the effect of temperature and substrate concentration on enzyme concentration allows better understanding of optimum conditions which enzymes can function. An example of an enzyme catalyzed reaction is enzymatic hydrolysis of an artificial substrate, o-Nitrophenylgalactoside (ONPG) used in place of lactose. Upon hydrolysis by B-galactosidase, a yellow colored compound o-Nitrophenol (ONP) is formed.
These enzymes have a secondary and tertiary structure and this could be affected by increases and decreases in temperature beyond the optimum temperature of the enzyme to work in. Mostly enzymes are highly affected any changes in temperature beyond the enzymes optimum. There are too
There are certain factors that alter how effective an enzyme might be in the reaction. Enzymes function better in warmer temperatures, the heat causes the molecules to move faster which increases the likelihood
Along with being found in plants, they are also present in liver cells, kidney cells, leukocytes and erythrocytes. For the concentration of enzyme experiment, the hypothesis was if the concentration of an enzyme increases, then the enzyme activity will increase as well. The hypothesis was proven to be true, because there are more enzymes to react with substrates. For the enzyme—factors affecting, the hypothesis concluded was if the temperature increases, than the enzyme activity will increase. This however was proven wrong, because enzymes become unstable at higher temperatures.