Proteins and Enzymes
Biomolecules: Proteins and Enzymes
What you'll learn
- The general structure of amino acids (H₂N—CHR—COOH) and the zwitterion form at physiological pH
- How to classify amino acids by their R group: acidic, basic, neutral, aromatic
- Peptide bond formation by condensation and properties of the —CO—NH— linkage
- The four levels of protein structure: primary, secondary, tertiary, quaternary
- The difference between fibrous and globular proteins with examples
- Denaturation — what it is, what causes it, and why it matters
- Enzyme catalysis: lock-and-key model, active site, inhibition types, optimum conditions
Level 1 Foundations
Amino Acids — Building Blocks of Proteins
An amino acid has both an amino group (—NH₂) and a carboxyl group (—COOH) attached to the same carbon atom (the α-carbon). The general structure is:
H
|
H₂N — C — COOH
|
R
The R group (side chain) determines the identity and properties of the amino acid.
Zwitterion (dipolar ion) form at physiological pH (~7.4):
H
|
⁺H₃N — C — COO⁻
|
R
At physiological pH, the —NH₂ group is protonated (—NH₃⁺) and the —COOH group is deprotonated (—COO⁻). The molecule is electrically neutral overall but carries both charges — called a zwitterion.
Isoelectric point (pI): The pH at which the amino acid has zero net charge (exists fully as zwitterion). At pH < pI → cation form; at pH > pI → anion form.
Classification of Amino Acids
Essential amino acids (cannot be synthesised by the body; must come from diet): Mnemonic: PVT TIM HaLL — Phenylalanine, Valine, Threonine, Tryptophan, Isoleucine, Methionine, Histidine, Arginine, Leucine, Lysine
| Category | R group character | Examples |
|---|---|---|
| Acidic | —COOH in R group (negative charge at pH 7) | Aspartic acid, Glutamic acid |
| Basic | —NH₂/guanidino in R group (positive charge at pH 7) | Lysine, Arginine, Histidine |
| Neutral | Non-ionisable R group | Glycine, Alanine, Serine |
| Aromatic | Benzene ring in R group | Phenylalanine, Tyrosine, Tryptophan |
| Sulphur-containing | —SH group | Cysteine, Methionine |
Glycine (R = H) is the simplest amino acid — it is the only amino acid with no chiral centre.
Peptide Bond Formation
When the —COOH of one amino acid reacts with the —NH₂ of another, a peptide bond (—CO—NH—) forms with loss of one water molecule (condensation reaction):
H₂N—CHR₁—COOH + H₂N—CHR₂—COOH
↓ (−H₂O)
H₂N—CHR₁—CO—NH—CHR₂—COOH
↑
peptide bond
Properties of the peptide bond:
- Partial double bond character (resonance with C=O group) → planar, rigid
- Trans configuration preferred (bulky R groups on opposite sides)
- Cannot freely rotate — restricts protein conformation
Nomenclature:
- 2 amino acids → dipeptide
- 3 → tripeptide
- Many → polypeptide or protein (roughly >50 amino acids)
Levels of Protein Structure
Primary Structure
- The linear sequence of amino acids in the polypeptide chain
- Held together by peptide bonds (covalent)
- Determines all higher levels of structure
- Example: Insulin — A chain (21 aa) + B chain (30 aa) linked by disulfide bridges
Secondary Structure The local spatial arrangement of the polypeptide backbone:
(a) α-Helix:
- Right-handed coil; each turn = 3.6 amino acids; pitch = 5.4 Å
- Stabilised by intramolecular H-bonds between C=O of residue n and N—H of residue n+4
- R groups project outward
- Example: Hair (keratin), myoglobin
(b) β-Pleated Sheet:
- Extended polypeptide chains running parallel or antiparallel
- Stabilised by intermolecular H-bonds between C=O and N—H of adjacent strands
- Example: Silk fibroin
Tertiary Structure
- The overall 3D folding of the entire polypeptide chain
- Stabilised by:
- Disulfide bonds (—S—S—) between cysteine residues (strongest; covalent)
- Hydrophobic interactions (nonpolar R groups cluster away from water)
- Ionic interactions (between acidic and basic R groups; "salt bridges")
- H-bonds (between polar R groups)
- Determines the protein's functional shape
Quaternary Structure
- Association of two or more polypeptide chains (subunits) into a functional protein
- Subunits held by same non-covalent interactions as tertiary structure
- Example: Haemoglobin — 4 subunits (2α + 2β), each carrying an O₂-binding haem group
Fibrous vs Globular Proteins
| Feature | Fibrous Proteins | Globular Proteins |
|---|---|---|
| Shape | Long, fibre-like | Compact, spherical |
| Solubility | Water-insoluble | Water-soluble |
| Function | Structural | Enzymatic, transport, regulatory |
| Examples | Keratin (hair, nails), collagen (tendons), fibroin (silk) | Haemoglobin, insulin, enzymes |
Denaturation
Denaturation is the loss of secondary, tertiary, and/or quaternary structure of a protein without breaking the primary structure (peptide bonds remain intact).
Causes of denaturation:
- Heat (disrupts H-bonds and hydrophobic interactions)
- Extreme pH (disrupts ionic interactions and H-bonds)
- Urea/guanidinium chloride (disrupts H-bonds by competing for donors/acceptors)
- Organic solvents (disrupt hydrophobic interactions)
- Heavy metal salts (form bonds with —SH, —COO⁻ groups)
Result: Loss of biological activity. Example: cooking an egg (albumin denatures → white coagulates); alcohol-based hand sanitiser (denatures bacterial proteins).
Renaturation (refolding): Some proteins can refold spontaneously if the denaturing agent is removed — proving that the primary sequence carries all the information needed for folding (Anfinsen's dogma).
Level 2 JEE Depth
Ramachandran Plot — Peptide Backbone Angles
The conformation of a polypeptide is defined by two backbone torsion angles: φ (phi) around N—Cα bond and ψ (psi) around Cα—C bond. The Ramachandran plot shows which φ,ψ combinations are sterically allowed. α-Helices and β-sheets cluster in distinct allowed regions — this is why not all sequences can form the same secondary structure.
Disulfide Bond Chemistry
Cysteine residues can oxidise to form a disulfide bridge (—S—S—):
2 R—SH → R—S—S—R + 2H⁺ + 2e⁻ (oxidation)
Disulfide bonds are the only covalent cross-links in tertiary/quaternary structure (apart from peptide bonds). They are reduced by reagents like β-mercaptoethanol or DTT. This is exploited in hair-perming (break —S—S— with reducer, reshape, re-oxidise).
Enzyme Catalysis — Detailed Mechanism
Enzymes are biological catalysts (mostly proteins, some RNA = ribozymes). They:
- Lower the activation energy (Eₐ) without being consumed
- Are highly specific (one enzyme catalyses one reaction type)
- Are reusable
Lock-and-key model (Fischer, 1894):
- The enzyme's active site has a rigid shape complementary to the substrate
- Substrate (key) fits exactly into the active site (lock)
- Enzyme–substrate complex (ES) forms → products released → enzyme regenerated
Induced-fit model (Koshland, 1958): The active site is not perfectly rigid; it changes shape slightly to optimally bind the substrate. More accurate model.
Michaelis-Menten equation (JEE awareness level):
Rate (v) = Vmax[S] / (Km + [S])
- Km (Michaelis constant) = [S] at half-maximum velocity → measures enzyme-substrate affinity
- Low Km = high affinity; High Km = low affinity
Enzyme Inhibition:
| Type | Mechanism | Effect on Vmax | Effect on Km |
|---|---|---|---|
| Competitive | Inhibitor resembles substrate; binds active site; reversed by excess substrate | Unchanged | Increased (apparent) |
| Non-competitive | Inhibitor binds elsewhere (allosteric site); changes enzyme shape | Decreased | Unchanged |
| Irreversible | Inhibitor covalently modifies active site | Enzyme destroyed | N/A |
Example — competitive inhibition: Malonate inhibits succinate dehydrogenase (resembles succinate). Used as pesticide model.
Optimum conditions:
- pH: Each enzyme has an optimal pH (e.g., pepsin pH ~2, salivary amylase pH ~7, trypsin pH ~8)
- Temperature: Rate increases up to optimum (~37°C for human enzymes); above it, denaturation occurs → rate drops sharply
Cofactors and Coenzymes
- Cofactor: Non-protein component required for enzyme activity
- Inorganic: Metal ions (Fe²⁺ in catalase, Zn²⁺ in carbonic anhydrase)
- Organic (coenzyme): Small organic molecule (e.g., NAD⁺, FAD, coenzyme A, vitamins)
- Apoenzyme: Protein part of the enzyme (inactive alone)
- Holoenzyme: Apoenzyme + cofactor (fully active)
Worked Examples
Example 1: Drawing a Dipeptide and Identifying the Peptide Bond
Problem: Write the structure of the dipeptide Gly-Ala (glycine followed by alanine).
Identify the peptide bond, N-terminus, and C-terminus.
Glycine: H₂N—CH₂—COOH (R = H)
Alanine: H₂N—CH(CH₃)—COOH (R = CH₃)
Condensation: —COOH of Gly + H₂N— of Ala → —CO—NH— + H₂O
Gly-Ala dipeptide:
H₂N—CH₂—CO—NH—CH(CH₃)—COOH
↑ ↑ ↑
N-terminus peptide bond C-terminus
Notes:
• The N-terminus (free —NH₂) is always written on the LEFT by convention.
• The C-terminus (free —COOH) is on the RIGHT.
• Gly-Ala and Ala-Gly are DIFFERENT dipeptides (different primary structure).
• The partial double bond character of —CO—NH— makes it PLANAR.
Example 2: Enzyme Inhibition — Competitive vs Non-Competitive
Problem: An enzyme has Vmax = 100 μmol/min and Km = 5 mM.
Inhibitor X increases apparent Km to 15 mM without changing Vmax.
Inhibitor Y decreases Vmax to 50 μmol/min without changing Km.
Classify each inhibitor and suggest what happens in each case.
Inhibitor X:
Vmax unchanged, Km increased (apparent affinity decreased)
→ COMPETITIVE inhibitor
→ Binds active site; competes with substrate
→ Adding more substrate can outcompete the inhibitor and restore full activity
Inhibitor Y:
Km unchanged, Vmax decreased
→ NON-COMPETITIVE inhibitor
→ Binds allosteric site (away from active site)
→ Causes conformational change; substrate can still bind but ES complex is less productive
→ Adding more substrate does NOT restore full Vmax
Key rule: If Km changes → competitive; if Vmax changes → non-competitive.
Common Mistakes
| Mistake | Why it's wrong | Correct thinking |
|---|---|---|
| Saying denaturation breaks peptide bonds | Denaturation only disrupts secondary, tertiary, and quaternary structure — the primary sequence (peptide bonds) is preserved | Denaturation = loss of 3D shape; the amino acid sequence remains intact |
| Treating α-helix H-bonds as between adjacent amino acids in sequence | The H-bond is between C=O of residue n and N—H of residue n+4 — not between neighbours | α-Helix H-bonds skip 3 residues; β-sheet H-bonds are between different strands |
| Confusing lock-and-key with induced-fit | Lock-and-key assumes a perfectly rigid active site; induced-fit (more accurate) allows the active site to change shape slightly on substrate binding | Induced-fit is now the accepted model; lock-and-key is a simplification |
| Saying competitive inhibitors lower Vmax | Competitive inhibition is reversible; at very high [S] the inhibitor is outcompeted and Vmax is reached | Competitive: Km↑, Vmax unchanged. Non-competitive: Vmax↓, Km unchanged |
Quick Check
- Draw the zwitterion form of alanine (R = —CH₃) at pH 7.
- How many peptide bonds are present in a polypeptide of 50 amino acids?
- Name the four types of interactions that stabilise tertiary protein structure.
- Haemoglobin has quaternary structure. What does this mean, and what is the subunit composition?
- (Stretch) The enzyme urease is inhibited by Ag⁺ ions. Explain the type of inhibition and the molecular basis. Would adding more substrate (urea) restore enzyme activity? Justify your answer.
NCERT Link & Exam Connections
- NCERT Class 12 Chemistry, Chapter 14 — Biomolecules, Sections 14.4–14.5
- JEE Foundation: 1–2 questions on protein levels, peptide bonds, enzyme inhibition types
- Common MCQ formats: identify primary/secondary/tertiary/quaternary structure, classify inhibition from Km/Vmax data
Study strategy: Memorise the 4 structural levels with their stabilising forces and one example each. For enzymes, practise classifying inhibition from data tables — competitive vs non-competitive is a high-yield MCQ topic.
Practice in Drishti
Practice MCQs on protein structure levels and enzyme inhibition in the Biomolecules — Proteins and Enzymes topic bank. Try Medium difficulty for JEE Foundation level.
Ask Drishti AI
Struggling to remember which level of protein structure involves disulfide bonds vs H-bonds? Ask the Drishti AI tutor to explain with a table of forces vs structure levels.
Track Your Progress
Complete the Quick Check questions and mark them in your Drishti progress tracker. Aim for 4/5 before moving to nucleic acids.
Next Steps
- Read: Biomolecules — Nucleic Acids — DNA double helix, base pairing, RNA types, central dogma
- Then: Vitamins and Hormones overview
- Practice: Mixed Biomolecules MCQs (Medium difficulty)
Key Takeaways (TL;DR)
- What you'll learn
- Level 1 Foundations
- Level 2 JEE Depth
- Worked Examples
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