Neutral Amino Acids
Amino acids which do not have any charge on them are neutral amino acids.
Globular Protein
The globular proteins refer to the shape of protein specifically spherical in nature apart from spherical form fibrous, disordered and membrane-bound proteins exist. These globular proteins are miscible in water and form a colloidal solution rather than other types which might not exhibit solubility. Many classes of the fold are found in globular proteins, which render them a sphere shape. Globular fold containing proteins usually are referred to by the term globin.
Dimer
Dimers are basic organic compounds, which are derivates of oligomers. It is formed by the combination of two monomers which could potentially be strong or weak and in most cases covalent or intermolecular in nature. Identical monomers are called homodimer, the non-identical dimers are called heterodimer. The method by which dimers are formed is known as “dimerization”.
Dipeptide
A dipeptide is considered a mixture of two distinct amino acids. Since the amino acids are distinct, based on their composition, two dipeptide's isomers can be produced. Various dipeptides are biologically essential and are therefore crucial to industry.
![Part 1. Effect of pH
The pH of an enzyme's environment can affect its activity by interfering with the charge on its
amino acids. Small changes in pH can result in enzyme denaturation and subsequent loss of catalytic
activity. Each enzyme has a characteristic optimum pH which usually falls within the physiological pH
range. Note that for the purpose of this experiment, distilled water has a pH of -7.00.
Watch this video and answer the related questions in the questions section of this activity.
The experiment in the video follows this procedure:
1. Prepare a water bath maintained at 37°C.
2. Mix the components shown in the table below:
Test Tube
1% Starch
0.2M NaCi
Acid/ Basel Water
Salivary
Solution
Amylase
A
10 mL
0.5 mL
1 mL 0.05 M HCI
2 mL
B
10 mL
0.5 mL
1 mL distilled water
2 mL
10 mL
0.5 mL
1 mL 0.05M NaOH
2 ml
3. Place the test tubes in a water bath.
4. Prepare a spot plate that contains two drops of I, in KI.
5. When the temperature of the test tube contents is 37°C, remove a few drops from the test
tubes and place them in the corresponding spot plates.
6. Withdraw another two drops every two minutes until a spot shows no color change.
Part 2. Effect of Temperature
As the temperature of an enzymatically catalyzed reaction increases, so does the speed of the
reaction. However, when the temperature goes beyond a certain point, it causes adverse effects on
the enzyme's tertiary structure. As a result, enzyme activity siows down. The temperature that allows
peak enzyme activity is known as the optimum temperature for that enzyme.
Watch this video and answer the related questions in the questions section of this activity.
The experiment in the video follows this procedure:
1. Based on the results from part 1, choose the mixture that showed high amylase activity.
2. Mix the components of this mixture in a different test tube except for the salivary amylase
which should be placed in a separate, smaller test tube.
3. Let the two test tubes equilibrate in a water bath maintained at 4°C for 10 minutes.
4. After 10 minutes, mix the saiivary amylase with the other components.
5. Prepare a spot plate with 9 of its wells containing two drops of I, in Kl each.
6. Remove a few drops from the test tubes and place them in the corresponding spot plate.
7. Withdraw another two drops every two minutes until all wells with I, in Kl are filled.
Repeat the same process but at 37°C and in 70°C.](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F27e0c982-efc4-4db2-93f4-d23f4cb14838%2F2bc3ed4d-029b-46ab-8f92-3f4fcd10a229%2Fz1htda_processed.jpeg&w=3840&q=75)
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