1.5.3 Enzymes

Cards (64)

What are enzymes and their role in biological reactions?
Biological catalysts
Each enzyme is specific to certain substrates
What is the primary structure of an enzyme?
Amino acid sequence
Secondary structure of enzymes arises from hydrogen bonds.
Match the tertiary structure bond with its description:
Hydrogen bond ↔️ Weak attraction between molecules
Disulfide bond ↔️ Strong covalent bond between sulfur atoms
Ionic bond ↔️ Attraction between oppositely charged ions
Hydrophobic bond ↔️ Interaction between nonpolar regions
The region within an enzyme where substrates bind is called the active site
What is the enzyme-substrate complex?
Temporary reactive intermediate
The enzyme-substrate complex lowers activation energy to facilitate catalysis.
How do enzymes lower activation energy in biological reactions?
By acting as catalysts
Lactase breaks down lactose into glucose and galactose
Arrange the levels of enzyme structure in order from simplest to most complex:
1️⃣ Primary
2️⃣ Secondary
3️⃣ Tertiary
4️⃣ Quaternary
What are the two models that describe enzyme-substrate interactions?
Lock-and-key and induced fit
The lock-and-key model describes enzymes with rigid active sites.
Which enzyme changes its shape to accommodate glucose in the induced fit model?
Hexokinase
The region within an enzyme crucial for lowering activation energy is the active site
The primary structure of an enzyme is the linear sequence of amino acids.
Secondary structures of enzymes include alpha helices and beta pleated sheets.
The tertiary structure of an enzyme is maintained by hydrogen, ionic, disulfide, and hydrophobic bonds.
Quaternary structures of enzymes involve the arrangement of multiple polypeptide subunits.
What is the region on an enzyme where substrates bind called?
Active site
The active site of an enzyme is crucial for lowering the activation energy of reactions.
Enzymes, being proteins, have four levels of structure.
Match the enzyme structure level with its bonding:
Primary ↔️ Peptide bonds
Secondary ↔️ Hydrogen bonds
Tertiary ↔️ Hydrogen, ionic, disulfide, hydrophobic bonds
Steps in the formation of the enzyme-substrate complex
1️⃣ Enzyme and substrate combine at the active site
2️⃣ Bonds such as hydrogen bonds and hydrophobic interactions form
3️⃣ Activation energy is lowered
4️⃣ Catalysis is facilitated
What are the two models that describe enzyme-substrate interaction?
Lock-and-key and induced fit
Match the enzyme-substrate interaction model with its description:
Lock-and-key ↔️ The active site precisely fits the substrate
Induced fit ↔️ The active site changes shape to fit the substrate
Enzyme activity is affected by temperature, pH, enzyme concentration, and substrate concentration.
Enzyme activity increases with temperature up to the optimal temperature, then decreases due to denaturation.
At what pH does enzyme activity peak?
Optimal pH
Increasing enzyme concentration always increases enzyme activity.
False
Excessive heat causes enzyme denaturation, reducing its activity.
What are enzyme inhibitors?
Substances that reduce activity
Match the type of enzyme inhibitor with its effect on Vmax and Km:
Competitive ↔️ Decreases Vmax, increases Km
Non-competitive ↔️ Decreases Vmax, Km unchanged
Non-competitive inhibitors bind to the active site of the enzyme.
False
What are enzyme inhibitors?
Substances that reduce activity
Competitive inhibitors bind to the active site of an enzyme.
Non-competitive inhibitors affect enzyme activity without binding to the active site.
Match the cofactors and coenzymes with their functions:
Cofactors ↔️ Stabilize enzyme structure
Coenzymes ↔️ Carry chemical groups
Which vitamin is NAD+ derived from?
Vitamin B3
Order the four levels of protein structure in enzymes:
1️⃣ Primary
2️⃣ Secondary
3️⃣ Tertiary
4️⃣ Quaternary