Introduction:
An Enzyme is a protein that in essence speeds up biological reactions. So that would mean that a Catalase is an enzyme reaction that decomposes hydrogen peroxide to water and oxygen. It is primarily found in the liver and it is important in protecting the cell from damaging oxidative reactions.
Since enzymes speed up chemical reactions, without them the reactions would take place way to slowly to actually do your body any good. It also stops the accumulation of cellular organelles. It is involved in several metabolic processes.
Enzymes have things called ‘Active Sites’ this the spot where substrates bind and chemical reaction takes place. Each enzyme has a different shape, this allows the enzyme to receive only one type of
…show more content…
They need to be broken down into simple sugars (monosaccharides) then digested/absorbed. In order to do this, the small intestine produces an enzyme called lactase. What lactase does is attaches itself to the lactose molecule and breaks it down into glucose and galactose. These molecules aren’t as big or complicated so they’re easily absorbed by the small intestine and into the bloodstream. Lactose Intolerance is when the body doesn’t actually produce the lactase enzyme, so the lactose can’t be broken down and absorbed. People with Lactose intolerance usually opt to take lactaid pills. The way these lactaid pills work is they contain the enzyme lactase that is responsible for the breakdown of lactose. You take these pills with the lactase in them and then now since your body now has the enzyme in needs to break down and absorb the lactose proceeds to do so. What people have recently found was that the pills don’t actually work due to the acidity levels in the stomach. So when you take the lactaid pills, they don’t make a difference because your stomach acids destroy the pills before they can take affect. What my results in Table 1 found that this was actually correct because, when the acid was introduced into this experiment it in essence rendered the pills completely useless. In Table 2 we found that, this issue was in fact due to the acidity because when you remove the acid, each test we did came back positive. Meaning that lactose was successfully metabolized/broken down into glucose. If we try and take account the sources of error that may have occurred during this lab, we have to take into account that these pills are recommended to be taken with food. So that while the pill is put into your system the stomach acids don’t destroy it because there is food in your system that it is already focused on. So maybe if we had mimicked the
Enzymes speed up metabolic reactions necessary for life. Without them certain vital processes would not take place and the body would be unable to function.
There are many types of enzymes and each has a specific job. Enzymes are particular types of proteins that help to speed up some reactions, such as reactants going to products. One of them is the amylase enzyme. Amylases are found in saliva, and pancreatic secretions of the small intestine. The function of amylase is to break down big molecules of starch into small molecules like glucose; this process is called hydrolysis. Enzymes are very specific; for example, amylase is the only enzyme that will break down starch. It is similar to the theory of the lock
Enzymes are biological catalysts that speed up chemical reactions, without being used up or changed. Catalase is a globular protein molecule that is found in all living cells. A globular protein is a protein with its molecules curled up into a 'ball' shape. All enzymes have an active site. This is where another molecule(s) can bind with the enzyme. This molecule is known as the substrate. When the substrate binds with the enzyme, a product is produced. Enzymes are specific to their substrate, because the shape of their active site will only fit the shape of their substrate. It is said that the substrate is complimentary to their substrate.
Enzymes are types of proteins that work as a substance to help speed up a chemical reaction (Madar & Windelspecht, 104). There are three factors that help enzyme activity increase in speed. The three factors that speed up the activity of enzymes are concentration, an increase in temperature, and a preferred pH environment. Whether or not the reaction continues to move forward is not up to the enzyme, instead the reaction is dependent on a reaction’s free energy. These enzymatic reactions have reactants referred to as substrates. Enzymes do much more than create substrates; enzymes actually work with the substrate in a reaction (Madar &Windelspecht, 106). For reactions in a cell it is
Enzymes are specific, this means that they only work on one substrate molecule. A substrate molecule is what the enzyme actually works on.
Enzymes are essentially proteins and will only act in an aqueous environment. An enzyme is specific for a certain reaction or
Lactose is a sugar that can be put into smaller molecules, glucose and galactose. Lactose is when you are not able to digest milk and dairy meaning that the enzyme lactase that breaks down lactose is not functioning properly. ONPG was used as a substitute for lactase because even though it is colorless it helps show enzyme activity by turning yellow. This experiment measured the absorbance ONPG when exposed to lactase within an environment of different salinity’s. The enzyme, lactase, was obtained by crushing a lactaid pill and then was added into four cuvettes. ONPG and salt solution of different concentrations were added and their levels of absorption was measured by a spectrophotometer. The results showed that higher salt concentrations have a lower level of absorption. There were 4 cuvettes and within those cuvettes that solutions within them were being tested and the results showed the more salt solution added with the lactase the lower the absorbance. The less salt solution there was a higher rate of absorbance. The data supported the hypothesis that with increasing NaCl concentration there would be a decrease in enzyme activity.
Enzymes are biological catalysts, which accelerate the speed of chemical reactions in the body without being used up or changed in the process. Animals and plants contain enzymes which help break down fats, carbohydrates and proteins into smaller molecules the cells can use to get energy and carry out the processes that allow the plant or animal to survive. Without enzymes, most physiological processes would not take place. Hundreds of different types of enzymes are present in plant and animal cells and each is very specific in its function.
Enzymes are proteins that act as catalysts during a biochemical process. Catalysts are non-changing enzymes that can increase or decrease activation energy to accelerate or slow down a biochemical reaction without using additional energy.
“Enzymes are proteins that have catalytic functions” [1], “that speed up or slow down reactions”[2], “indispensable to maintenance and activity of life”[1]. They are each very specific, and will only work when a particular substrate fits in their active site. An active site is “a region on the surface of an enzyme where the substrate binds, and where the reaction occurs”[2].
Organisms cannot depend solely on spontaneous reactions for the production of materials because they occur slowly and are not responsive to the organism's needs (Martineau, Dean, et al, Laboratory Manual, 43). In order to speed up the reaction process, cells use enzymes as biological catalysts. Enzymes are able to speed up the reaction through lowering activation energy. Additionally, enzymes facilitate reactions without being consumed (manual,43). Each enzyme acts on a specific molecule or set of molecules referred to as the enzyme's substrate and the results of this reaction are called products (manual 43). As a result, enzymes promote a reaction so that substrates are converted into products on a faster pace (manual 43). Most enzymes are proteins whose structure is determined by its sequence of its amino acids. Enzymes are designed to function the best under physiological conditions of PH and temperature. Any change of these variables that change the conformation of the enzyme will destroy or enhance enzyme activity(manual, 43).
Enzymes are central to every biochemical process. Due to their high specificity they are capable of catalyzing hundreds of reactions that signifies their vast practical importance.
Each enzyme is very specific and can only catalyze a certain reaction. The specific reaction catalyzed by an enzyme depends on the molecular structure and shape of a small area of the enzyme’s surface called the active site. The active site an attract and hold only its specific molecules. The target molecule that the enzyme attracts and acts upon is called the substrate. The substrate and the active site of the molecule must fit together very closely. Sometimes the enzyme changes its shape slightly to bring about the necessary fit.
Enzymes are very efficient catalysts for biochemical reactions. They speed up reactions by providing an alternative reaction pathway of lower activation energy. Like all catalysts, enzymes take part in the reaction - that is how they provide an alternative reaction pathway. But they do not undergo permanent changes and so remain unchanged at the end of the reaction. They can only alter the rate of reaction, not the position of the equilibrium. Enzymes are usually highly selective, catalyzing specific reactions only. This specificity is due to the shapes of the enzyme molecules.
Within a cell, enzymes are used as a catalyst to increase the rate of chemical reaction. They do not consume themselves, rather they help in increasing the rate of reaction. Within the body, enzymes vary depending on their specific functions. For instance, hydrogen peroxide is a toxic chemical, but it breaks down into harmless oxygen and water. This reaction can be sped up using the enzyme catalyst produced by yeast. Hydrogen peroxide is produced as a byproduct in cellular reaction, because it is poisonous and must be broken down, therefore this reaction is important. The speeding up of the reaction is shown below: