LAS 3 - Proteins Part 1 PDF

Summary

This document details lab questions and procedures for isolating various proteins, including gluten, bean proteins, and myoglobin from different sources. It also discusses the characterization of proteins using various laboratory tests.

Full Transcript

PROTEINS

ISOLATION OF PROTEIN
Isolation of Gluten
- Crude gluten - is a mixture of proteins extracted from wheat flour. It's primarily
composed of two proteins: glutenin and gliadin. These proteins are responsible for the
elastic properties of dough, allowing it to be stretched and molded.
Isolation of Bean Protein
- 1M Acetic Acid - The one who precipitates the bean protein from the mixture.
Isolation of Myoglobin from Muscle
Isolation of Albumin from Egg White

POST LABORATORY QUESTIONS
Isolation of Gluten
1. State the relationship of iodine test and complete removal of starch
- The iodine test is used to determine the presence of starch. The starch reacts
with iodine to produce a blue-black color. Therefore, when the solution is no
longer blue-black when tested on the wash water of the dough, it signifies that all
starch has been completely washed out.
2. How does the amount of the insoluble material left compare with the amount of the
original sample used?
- The amount of insoluble material left is significantly less than the original amount
of wheat flour. This is because the majority of the wheat flour is composed of
starch and starch is soluble in water and could be washed away during the
process. The gluten which is insoluble in water remains as a residue.
3. What composes crude gluten?
- Crude gluten is primarily composed of two proteins: glutenin and gliadin. These
proteins are responsible for the elastic properties of dough, allowing it to be
stretched and molded.

Isolation of Bean Protein
1. State the purpose of soaking the beans in water
- Soaking the beans in water hydrates the beans, softening it making it easier to
grind. This process also helps activate enzymes in the beans which can break
down complex carbohydrates making protein extraction more efficient.
2. What are the predominant proteins present in beans?
- The predominant proteins in beans are legumins and globulins. These are
storage proteins that provide a rich source of amino acids.
3. How are these bean proteins precipitated by an acid?
- Bean proteins are precipitated by acid due to the isoelectric point (pI) of the
proteins. The pI is the pH at which a protein has no net electrical charge. When
the pH of the solution is adjusted to the pI of the protein, the solubility of the
 protein decreases, leading to precipitation. Acetic acid, being an acid, lowers the
pH of the solution, causing the bean proteins to precipitate out.
- The addition of acetic acid causes the bean protein to gain positive charges from
being an isoelectric point (no charges), this gain of positive charges causes the
bean protein to repel the charges of the hydrogen ion of the water thus
precipitating out.

Classify the following proteins according to their biological functions and describe:

Proteins Class of biological function Description of the function

Albumin Transport protein Maintains osmotic pressure in
blood, transports fatty acids,
hormones, drugs, and other
substances.

Gluten Structural protein Provides elasticity and
viscosity to dough, forming
the structure of bread and
other baked goods.

Myoglobin Storage protein Stores oxygen in muscle
tissue for use during cellular
respiration.

CHARACTERIZATION OF PROTEINS (SUMMARY)
Concentrations of isolated protein from the experiment:
Gluten - 0.5g each test tubes
Bean Protein - Precipitated bean protein is diluted using 15 ml distilled H2O (3ml each test
tubes)
Albumin - 3 ml each test tubes

Test Test for presence Color

Biuret Test General test for proteins, at Purple/Violet
least 2 peptide bonds

Ninhydrin Test Amino acid Blue/Violet

Millon’s Test Tyrosine & phenol solution Brick Red PPT

Hopkins-Cole Test Tryptophan Purple Ring

Lead Acetate test Sulfur containing amino acids Black to Brown
 (Methionine, cysteine,
homocysteine, and taurine)

Xanthoproteic Test Aromatic amino acids (e.g. Yellow
tyrosine, tryptophan and
phenylalanine)

Sakaguchi Test Arginine Red

CHARACTERIZATION OF PROTEINS (PRINCIPLE)
General Test
Biuret Test
- The Biuret test detects the presence of peptide bonds, which are indicative of
proteins. When a protein solution is mixed with Biuret reagent (a solution of copper
sulfate), the peptide bonds in the protein complex with copper ions (Cu²⁺) under alkaline
conditions. This complex forms a violet or purple color, indicating the presence of
proteins. The intensity of the color is proportional to the number of peptide bonds,
which correlates with protein concentration.

Ninhydrin Test
- The Ninhydrin test is used to detect free amino acids. When Ninhydrin reacts with
the free amino group (-NH₂) of amino acids, it undergoes a decarboxylation reaction,
resulting in the formation of a blue or purple-colored compound known as
Ruhemann's purple. This reaction is sensitive and can detect even small amounts of
amino acids. Ninhydrin also reacts with peptides and proteins but with a different color
intensity

Specific Test
Millon’s Test
- Millon’s test is specific for detecting phenolic compounds, particularly the amino
acid tyrosine. In this test, Millon's reagent (mercuric nitrate in nitric acid) reacts with the
phenolic group of tyrosine when heated. This reaction produces a red-colored
complex, indicating the presence of tyrosine in the sample. This test is useful for
distinguishing proteins that contain tyrosine from those that do not.

Hopkins-Cole Test
- The Hopkins-Cole test is specific for the detection of the amino acid tryptophan. In
this test, the protein sample is mixed with glyoxylic acid and concentrated sulfuric
acid. The indole ring of tryptophan reacts with glyoxylic acid under acidic conditions,
forming a violet ring at the interface of the two liquids. This test is used to confirm the
presence of tryptophan in proteins.
Lead Acetate Test
- The Lead Acetate test is used to detect sulfur-containing amino acids, such as
cysteine. When a protein containing cysteine is treated with lead acetate, the sulfur in
cysteine forms a black precipitate of lead sulfide (PbS). This reaction indicates the
presence of cysteine or other sulfur-containing amino acids in the protein.

Xanthoproteic Test
- The Xanthoproteic test detects aromatic amino acids, particularly tyrosine,
tryptophan, and phenylalanine. When proteins are treated with concentrated nitric
acid, the aromatic rings of these amino acids undergo nitration, resulting in a
yellow-colored complex. Upon addition of an alkali, the color intensifies to orange,
confirming the presence of aromatic amino acids.

Sakaguchi Test
- The Sakaguchi test specifically detects the amino acid arginine. In this test, the
guanidine group of arginine reacts with α-naphthol and sodium hypochlorite under
alkaline conditions to form a red-colored complex. The presence of a red color
indicates the presence of arginine in the protein sample.