Enzymes: Need to Know

Questions and Answers

What happens to albumen when it is denatured?

It dissolves completely.

It becomes stiff and white. (correct)

It becomes clear and runny.

It remains unchanged.

At what pH does salivary amylase optimally function?

3

1

7-8 (correct)

10

What effect does an acidic pH have on salivary amylase?

It makes it more efficient in breaking down starch.

It enhances its enzyme activity.

It denatures the enzyme and halts digestion. (correct)

It causes irreversibility of the enzyme.

What is formed when a substrate binds to an enzyme's active site?

Enzyme-substrate complex.

Which of the following reactions is characterized as anabolic?

Synthesizing proteins from amino acids.

What is the primary role of agitation, such as shaking or beating, in enzyme activity?

It denatures the enzyme.

What can be inferred about the enzyme's original shape after product formation?

It regains its original shape.

What term describes a substance that assists an enzyme in functioning properly?

Co-enzyme

At what pH does pepsin, an enzyme that acts on proteins in the stomach, work best?

pH 2

What happens to enzymes when the temperature exceeds 40°C?

Enzymes may denature

Which enzyme is known to work optimally at pH 10?

Lipase

Which of the following statements about enzymes is true?

Enzymes are specific and work on one substrate.

How do co-enzymes differ from enzymes?

Co-enzymes enhance the function of enzymes.

What is a common consequence of an enzyme being denatured?

The enzyme loses its activity.

What primarily affects the function of enzymes according to their environmental conditions?

pH and temperature

Study Notes

Enzymes Overview

• Enzymes are proteins that act as biological catalysts, accelerating chemical reactions without being consumed.
• Each enzyme is specific to one substrate and produces only a specific set of products.
• Made from long chains of amino acids linked by peptide bonds; their structure is folded into a unique 3D shape.

Co-enzymes

• Some enzymes require additional molecules, known as co-enzymes, for optimal function.
• Co-enzymes are organic, non-protein substances; vitamins B1 and B6 function in this role.
• Enzyme names typically end with the suffix ‘-ase’.

Factors Affecting Enzyme Activity

• Enzyme function is influenced by environmental conditions such as pH, temperature, concentration of enzymes, and substrates, as well as the presence of inhibitors.

pH Impact

• Each enzyme has a specific pH range for optimal activity:
  • Amylase: best at pH 7 (neutral).
  • Pepsin: functions optimally around pH 2 (acidic), suited for the stomach.
  • Lipase: works best at pH 10 (alkaline) in the small intestine.

Temperature Impact

• Enzyme activity typically increases with temperature, peaking at around 40°C.
• Above 40°C, enzymes rapidly denature, losing shape and function.
• Human enzymes function optimally around 37°C but can become inactive above this temperature, particularly in the brain, risking seizures.
• Plant enzymes thrive at an approximate optimum temperature of 25°C.

Denatured Enzymes

• Denaturation refers to the loss of an enzyme's shape and activity, caused by several factors:
  • High Temperature: Enzymes lose shape above 40°C; irreversible changes occur at temperatures exceeding 50°C. For example, egg whites transition from clear to stiff upon heating.
  • pH Change: For instance, salivary amylase, which breaks down starch at pH 7-8 in the mouth, becomes inactive when exposed to the acidic environment (pH 1) in the stomach.
  • Agitation: Physical mixing or beating can alter enzyme shape and activity, such as when egg whites are beaten, forming a thick mixture that traps sugar.

Active Site Theory

• The active site is the specific region on the enzyme where the substrate binds and reactions occur.
• The binding causes slight shape changes in both substrate and enzyme, forming an enzyme-substrate complex.
• These transformations facilitate product formation and lower activation energy needed for the reaction.
• Resulting products may form a substrate-product complex, allow the enzyme to revert to its original shape, ready to catalyze another reaction.

Types of Reactions

• Anabolic Reactions: Create more complex products from simpler reactants; e.g., muscle formation.
• Catabolic Reactions: Break down complex reactants into simpler products; oppositely, they release energy.

Description

This quiz covers essential information about enzymes, including their role as biological catalysts, specificity for substrates, and structural composition. Understand how enzymes facilitate chemical reactions in cells and the importance of their 3D shape for function.