In this lab we experimented with pH, spectrophotometry, and enzymes like catecholase. We used spectrophotometry to detect how enzyme activity would change under different pH, temperature, enzyme concentration, and substrate concentration. Enzymes are important for biochemical reactions because they speed up the process and allow the organism to continue living. The enzyme used in the experiment is catecholase and it catalyzes a reaction between catechol and water. We analyzed the samples in the spectrophotometry and it is measured by absorbance and transmittance and this will allow us to see which sample will have the largest concentration of molecules. The first experiment involved enzyme concentration and enzyme activity; in this experiment …show more content…
We increased the substrate, catechol, while maintaining the enzyme, catecholase, at the same volume. We came to the hypothesis that if the substrate was increased, then the rate of reaction would increase as long as there is enzymes to react with. The third experiment involved how temperature would affect enzyme activity. This was done by placing certain vials in certain temperatures and then analyzing the data in the spectrophotometer. We came to the hypothesis that if the temperature was increased, then the reaction rate would increase until it reaches the optimal temperature after that the reaction rate would decrease. This is because the enzyme will start to denature if the temperatures get too high or too low. The fourth experiment deals with how pH affects enzyme activity. For this experiment different vials with catecholase and different pH’s were observed under a spectrophotometer to see how the enzyme would be affected. We found our hypothesis to be, if pH is raised, then the reaction rate will increase until it reaches the optimal pH. The reaction rate will increase until the optimal pH because after the optimal pH, the enzyme will start to denature and not function as it
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
Students will be observing normal catalase reaction, the effect of temperature on enzyme activity, and the effect of pH on enzyme activity in this experiment. The enzymes will all around perform better when exposed in room temperature than when it is exposed to hot and cold temperatures. This is based on the fact that the higher the temperature, the better the enzymes will perform, but as the temperature reaches a certain high degree, the enzymes will start to denature, or lose their function.
Introduction: Starting out with some background information, I know that enzymes are biological catalysts. The enzyme that I used for this experiment was potato juice. Enzymes make reaction rates go faster. They lower activation energy, making chemical reactions. Temperature has an effect on canola cultivars. The higher temperature decreased stem diameter, but room temperature had thicker stems. So I believe the same will happen for the catechol oxidase; the solution will react faster at room temperature. Other enzymes can also have different effects such as the enzyme in cattle serum. The enzyme lost activity in room temperature. With that being said room temperature can also be detrimental with specific enzymes. Fungus also
Background and Introduction: Enzymes are proteins that process substrates, which is the chemical molecule that enzymes work on to make products. Enzyme purpose is to increase the rate of activity and speed up chemical reaction in a form of biological catalysts. The enzymes specialize in lowering the activation energy to start the process. Enzymes are very specific in their process, each substrate is designed to fit with a specific substrate and the enzyme and substrate link at the active site. The binding of a substrate to the active site of an enzyme is a very specific interaction. Active sites are clefts or grooves on the surface of an enzyme, usually composed of amino acids from different parts of the polypeptide chain that are brought together in the tertiary structure of the folded protein. Substrates initially bind to the active site by noncovalent interactions, including hydrogen bonds, ionic bonds, and hydrophobic interactions. Once a substrate is bound to the active site of an enzyme, multiple mechanisms can accelerate its conversion to the product of the reaction. But sometimes, these enzymes fail or succeed to increase the rate of action because of various factors that limit the action. These factors can be known as temperature, acidity levels (pH), enzyme and/or substrate concentration, etc. In this experiment, it will be tested how much of an effect
Lab six requires students to observe the effects of pH and enzyme concentration on catecholase activity. Enzymes are organic catalysts that can affect the rate of a chemical reaction depending on the pH level and the concentration of the enzyme. As pH comes closer to a neutral pH the enzyme is at its greatest effectiveness. Also at the absorbance of a slope of 0.0122 the enzyme is affected greatly. The pH effect on enzymes can be tested by trying each pH level with a pH buffer of the same pH as labeled as the test tube and 1mL of potato juice, water, and catechol. This is all mixed together and put in the spectrophotometer to test how much is being absorbed at 420nm. As the effect on enzyme concentration can be tested almost the same way. This part of the exercise uses different amounts of pH 7-phosphate buffer and potato juice, and 1mL of catechol mixed together in a test tube. Each substance is put in the spectrophotometer at a wavelength set tot 420nm. The results are put down for every minute up to six minutes to see how enzyme concentration affects reaction rate. The results show that the pH 8 (0.494) affects the enzyme more than a pH of 4 (0.249), 6 (0.371), 7 (0.456), and 10 (0.126). Also the absorbance is greatest at a slope of 0.0122 with test tube C that has more effect on the reaction rate, than test tube A, B, and D.
This lab was performed in order to discover the activity of the enzyme catecholase in different pH levels as well as its absorbance in differently concentrated solutions. A spetrophotometer was used to measure the absorbance of the enzyme catecholase in different pH solutions as well as to measure the absorbance of catecholase in solutions with different concentrations of potato juice and phosphate buffers. Absorbance of the enzyme catecholase was at an optimum level when pH was close to neutral. When pH was acidic or basic, the catecholase was less effective. Also, when there was a higher concentration of potato juice and a lower concentration of phosphate buffer, absorbance of the enzyme increased.
Knowing that a certain substrate will turn yellow when it reacts with a certain enzyme, you can have samples of test tubes with different concentrations that substrate, as well as a test tube with the original concentration as a control group. By adding the same amount of enzymes to each of the test tubes, you can use the spectrophotometer in order to see the yellow color from test tubes due to the chemical reactions that occur. After observing each test tube, you can then determine if the test tubes containing the higher concentrations of substrate ended up with a more saturated yellow color than the original
However, the rate of reaction only increases for a certain period of time until there is lesser substrate molecules than the enzyme molecules. The increase of enzyme concentration does not have effect if there are lesser substrate molecules than enzyme molecules initially.
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 high molecular weight molecules and are proteins in nature. Enzymes work as catalysts in biochemical reactions in living organisms. Enzyme Catecholase is found on in plants, animals as well as fungi and is responsible for the darkening of different fruits. In most cases enzymatic activities are influenced by a number of factors, among them is temperature, PH, enzyme concentration as well as substrate concentration (Silverthorn, 2004). In this experiment enzyme catecholase was used to investigate the effects of PH and enzyme concentration on it rate of reaction. A pH buffer was used to control the PH, potato juice was used as the substrate and water was used as a solvent.
The biggest problem my group experienced was that as we moved into our second round of trails, we noticed consistently higher reaction times for the same concentration of enzyme. There are two possible explanations for this. The first is that we continued to use the same container of hydrogen peroxide every trail. The peroxide may have become diluted, reducing the rate at which the reaction could happen. This became apparent when we got to the lowest concentration trails. We were reasonably sure that these would both take a long time, so we did both trails simultaneously in two different containers: one old, one new. The trail conducted in the container of fresh peroxide finished in just over six minutes, however the trail conducted in the used
The purpose of this experiment is to determine if an increase in enzyme concentration will initiate an increase in the rate of emyzmatic activity and if a decrease in enzyme concentration will initiate a decrease in rate of enzymatic activity. To determine if that is correct there will be a test to determine the pressure in the enzyme concentration when there is 5,10, and
a. The enzyme of this experiment is the catalase from the potatoes. Catalase is an enzyme present in humans that breakdown peroxide (H2O2), a toxic substance to organisms but is a byproduct of biochemical reaction. Catalase is found in peroxisomes within cells, and typically breakdown the hydrogen peroxide (if any) produced within the cell before it is able to leave. This makes catalase an extremely vital enzyme as it basically prevents the toxin from doing any true harm. b.
This experiment is designed to analyze how the enzyme catalase activity is affected by the pH levels. The experiment has also been designed to outline all of the directions and the ways by which the observation can be made clearly and accurately. Yeast, will be used as the enzyme and hydrogen peroxide will be used as a substrate. This experiment will be used to determine the effects of the concentration of the hydrogen peroxide versus the rate of reaction of the enzyme catalase.
It was hypothesized that the catalase enzyme would decrease in activity after a significant change in temperature, pH, substrate concentration and enzyme concentration from the optimal range of conditions. There are specific conditions in which the enzyme, catalase, will be most effective and have the fastest reaction rate and conditions where the reaction rate will be the slowest. The hypothesis states that the optimal conditions