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General role of enzymes
Role of enzymes in medicine
Effect of ph on alkaline phosphatase
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Recommended: General role of enzymes
Enzyme activity can be effected by a series of factors such as pH, temperature, and concentration of enzyme (Campbell, 2014). The purpose of this experiment is to determine the specific effects due to the change in pH, temperature, and concentration on the enzyme activity of the Alkaline Phosphatase Enzyme. The results displayed the effects of the Alkaline Phosphatase Enzyme due to the shifts in environment. The temperature shift revealed the enzyme’s optimal temperature for it’s to function ideally. The concentration increase within the enzyme resulted in the increase in enzyme activity. The pH levels showed that the Alkaline Phosphatase Enzyme was most ideal under neutral conditions. The ideal functioning of the Alkaline Phosphatase Enzyme in neutral pH levels is associated with how the enzyme is present within cells and extracellular fluid matrices with similar environments. The specific increase in enzyme activity due to temperature and concentration is correlated to the rate of reaction theory. In overall, the experiment remain parallel with the theories presented with …show more content…
The null of this hypothesis is that the increase in pH will not have effect the enzyme activity of the Alkaline Phosphatase Enzyme. It is also hypothesizes that the increase in concentration of the alkaline phosphatase enzyme will increase the enzyme activity of the Alkaline Phosphatase Enzyme. The null hypothesis for the concentration is that the increase in concentration of the alkaline phosphatase enzyme will not increase the enzyme activity of ALP. For the temperature, it is hypothesize that the increase in the temperature of the alkaline phosphatase enzyme will increase the catalytic rate of the Alkaline Phosphatase Enzyme. The null hypothesis for the temperature is that the increase in the temperature will not increase the catalytic rate of the Alkaline Phosphatase
After conducting this experiment and collecting the data I would have to say that the optimal temperature for enzyme activity would have to be room temperature which in my experiment was thirty-four degrees Celsius. I came to this answer because the glucose test strip showed that at room temperature there was more glucose concentration that at either of the other temperatures. Due to temperature extremes in the boiling water the enzymes could no longer function because the breakdown of lactose stopped. The cold water also hindered the breakdown of the lactose but as the water warmed the enzymes were more active which can be seen in the results for the cold water at 20 minutes B. Describe the relationship between pH and the enzymatic activity of lactase.
The affects of pH, temperature, and salt concentration on the enzyme lactase were all expected to have an effect on enzymatic activity, compared to an untreated 25oC control. The reactions incubated at 37oC were hypothesized to increase the enzymatic activity, because it is normal human body temperature. This hypothesis was supported by the results. The reaction incubated to 60oC was expected to decrease the enzymatic activity, because it is much higher than normal body temperature, however this hypothesis was not supported. When incubated to 0oC, the reaction rate was hypothesized to decrease, and according to the results the hypothesis was supported. Both in low and high pH, the reaction rate was hypothesized to decrease, which was also supported by the results. Lastly, the reaction rate was hypothesized to decrease in a higher salt concentration, which was also supported by the results.
The shape of the molecules is changing and so the enzyme molecules can no longer fit into the gaps in the substrate that they need to and therefore the enzymes have de – natured and can no longer function as they are supposed to and cannot do their job correctly. Changing the temperature: Five different temperatures could be investigated. Water baths were used to maintain a constant temperature. Water baths were set up at 40 degrees, 60 degrees and 80 degrees (Celsius). Room temperature investigations were also carried out (20 degrees).
The Effect of Temperature on the Activity of the Enzyme Catalase Introduction: The catalase is added to hydrogen peroxide (H²0²), a vigorous reaction occurs and oxygen gas is evolved. This experiment investigates the effect of temperature on the rate at which the enzyme works by measuring the amount of oxygen evolved over a period of time. The experiment was carried out varying the temperature and recording the results. It was then repeated but we removed the catalase (potato) and added Lead Nitrate in its place, we again tested this experiment at two different temperatures and recorded the results. Once all the experiments were calculated, comparisons against two other groups were recorded.
Investigating the Effect of Substrate Concentration on Catalase Reaction. Planning -Aim : The aim of the experiment is to examine how the concentration of the substrate (Hydrogen Peroxide, H2O2) affects the rate of reaction. the enzyme (catalase).
Alkaline Phosphatase (APase) is an important enzyme in pre-diagnostic treatments making it an intensely studied enzyme. In order to fully understand the biochemical properties of enzymes, a kinetic explanation is essential. The kinetic assessment allows for a mechanism on how the enzyme functions. The experiment performed outlines the kinetic assessment for the purification of APase, which was purified in latter experiments through the lysis of E.coli’s bacterial cell wall. This kinetic experiment exploits the catalytic process of APase; APase catalyzes a hydrolysis reaction to produce an inorganic phosphate and alcohol via an intermediate complex.1 Using the Michaelis-Menton model for kinetic characteristics, the kinetic values of APase were found by evaluating the enzymatic rate using a paranitrophenyl phosphate (PNPP) substrate. This model uses an equation to describe enzymatic rates, by relating the
5. Decreasing or increasing the pH slowed the rate of reaction. The pH of 7 was the best for the reaction. If there are more H or more OH in the solution then the reaction is inhibited, because they disrupt the active site.
Enzymes are very specific in nature, which helps them in reactions. When an enzyme recognizes its specific substrate, the enzyme binds to the substrate in a region called the active site which is made of amino acids. Once the substrate binds, the enzyme changes its shape slightly to make an even tighter fit around the substrate, This is called induced fit and it allows for the enzyme to catalyze the reaction more easily. Another factor contributing to catalyses is the amount of substrate present; the more substrate molecules available, the more often they bind the active site. Once all of the enzyme's active sites are occupied by substrate, the enzyme is saturated ( Campbell 99). Enzyme's have optimal conditions under which they perform. These include temperature, pH, and salt concentration, amongst others. In this lab we only focused on pH and temperature. Each enzyme is specific to a certain optimal temperature and pH. When conditions are favorable, the reaction takes place at a faster rate, allowing for more substrates to collide with active sites of enzymes. However, if conditions get too extreme, the enzyme...
Input variables In this experiment there are two main factors that can affect the rate of the reaction. These key factors can change the rate of the reaction by either increasing it or decreasing it. These were considered and controlled so that they did not disrupt the success of the experiment. Temperature-
The Effect of pH on Enzyme Activity. pH is a measure of the concentration of hydrogen ions in a solution. The higher the hydrogen ion concentration, the lower the pH. Most enzymes function efficiently over a narrow pH range. A change in pH above or below this range reduces the rate of enzyme reaction. considerably.
The aim of my investigation is to find out whether the increase of temperature increases the rate of reaction between the two reactants of Sodium Thiosulphate and Hydrochloric acid. I will then find out and evaluate on how temperature affects this particular reaction. Factors There are four main factors, which affect the rate of reaction that are considered as variables for the experiment I will be doing, they are the following: Molecules can only collide when two of them meet together.
The effect of a change in PH on enzymes is the alteration in the ionic
However, the decrease varied depending on the temperature. The lowest temperature, 4 degrees Celsius, experienced a very low decrease of amylose percentage. Temperature at 22 degrees Celsius and 37 degrees Celsius, both had a drastic decrease in amylose percentage. While the highest temperature, 70 degrees Celsius, experienced an increase of amylose percentage. In conclusion, as the temperature increases the percentage of amylose decreases; however, if the temperature gets too high the percentage of amylose will begin to increase. The percentage of amylose increases at high temperatures because there is less enzyme activity at high temperatures. However, when the temperature is lower, more enzyme activity will be present, which results in the decrease of amylose percentage. This is why there is a decrease of amylose percentage in 4, 22, and 37 degrees Celsius. In this experiment the optimal temperature is 37 degrees Celsius, this is because this is the average human body temperature. Therefore, amylase works better at temperatures it is familiar
Purpose: This lab gives the idea about the enzyme. We will do two different experiments. Enzyme is a protein that made of strings of amino acids and it is helping to produce chemical reactions in the quickest way. In the first experiment, we are testing water, sucrose solution, salt solution, and hydrogen peroxide to see which can increase the bubbles. So we can understand that enzyme producing chemical reactions in the speed. In the second experiment, we are using temperature of room, boiling water, refrigerator, and freezer to see what will effect the enzyme.
5 test tubes were prepared for dilution respectively to 5 spec tubes that had the inhibitor and water and ready for the enzyme addition. Recordings were done every 60 seconds for 3 minutes. Reaction rate was then calculated after time ended. After having used the inhibitor, the steps were repeated but replace the inhibitor with water as control and experimented for the rates without the inhibitor. Percentages were graphed by the percentage inhibition versus the substrate concentration for the inhibitor. Part 5 of the experiment was to determine the effect of temperature or pH on the reaction rate. In doing so, each group in the lab was designated a particular enzyme that was exposed in different temperatures (Schultz, 2006). The enzymes were exposed before the beginning of the experiment into these different temperatures: boiling, warm (heat), room temperature, cold (ice bath), and frozen. Each enzyme was allowed back to room temperature before adding the buffered catechol with the 1 ml of enzyme into the spec tube (Schultz, 2006). Reaction rate was then determined from the reading. Absorbance versus time was plotted with the determined initial rate of each