Hydrolysis | Macromolecules | Biology | Khan Academy

Khan Academy

13 Jul 201508:28

Summary

TLDRThe video script delves into the process of dehydration synthesis, illustrating how glucose molecules form disaccharides like maltose and longer polysaccharides such as starch, glycogen, and cellulose. It highlights the structure and function of these carbohydrates in nature and within organisms. The script also explains the reverse process, hydrolysis, detailing how these complex carbohydrates are broken down into glucose for energy utilization in biological systems.

Takeaways

🧬 Dehydration synthesis is the process where monosaccharides like glucose form bonds to create disaccharides like maltose and polysaccharides.
🍚 Starch, found in foods like mashed potatoes, is a polysaccharide composed mainly of glucose chains.
🦂 Chitin, a polysaccharide similar to starch, forms the exoskeleton of insects and crustaceans like lobsters.
🏃 Glycogen, stored in our muscles, is a polysaccharide that serves as an energy reserve and is made of glucose chains.
🌳 Cellulose, a major component of plant cell walls, paper, and wood, is a polysaccharide with glucose chains arranged differently from starch.
💭 Cotton is nearly pure cellulose, with about 90 percent of its composition being this polysaccharide.
🔬 The structure of cellulose is unique due to the hydrogen bonds formed between oxygen atoms and hydrogen atoms across different glucose chains.
🍽 Hydrolysis is the process used to break down polysaccharides into monosaccharides, such as glucose, using water.
🚰 The prefix 'hydro' in hydrolysis indicates the involvement of water, while 'lysis' means breaking down.
🔄 Hydrolysis is essentially the reverse of dehydration synthesis, involving the breaking of bonds with the help of water molecules.
🛠️ The hydrolysis mechanism involves the transfer of hydrogen protons and the formation and breaking of covalent bonds, leading to the release of individual glucose molecules.

Q & A

What is the process of dehydration synthesis in the context of carbohydrates?
-Dehydration synthesis is a chemical reaction where two molecules combine to form a larger molecule, with the removal of a water molecule. In the context of carbohydrates, this process allows monosaccharides like glucose to bond together, forming disaccharides or polysaccharides.
What is maltose and how is it formed?
-Maltose is a disaccharide formed when two glucose molecules bond together through a dehydration synthesis reaction. It is a simple example of how monosaccharides can combine to form larger carbohydrate structures.
What are polysaccharides and how do they differ from disaccharides?
-Polysaccharides are complex carbohydrates consisting of long chains of monosaccharide units, often glucose. They differ from disaccharides, which are only two monosaccharide units linked together, in that polysaccharides can have many more monosaccharide units and can be derived from various sources.
What is the primary component of mashed potatoes and how is it related to glucose?
-The primary component of mashed potatoes is starch, which is a polysaccharide made up of long chains of glucose molecules. This shows the prevalence of glucose as a building block in various carbohydrate structures.
What is chitin and how is it similar to starch?
-Chitin is a polysaccharide found in the exoskeletons of insects and crustaceans, as well as in the cell walls of fungi. It is similar to starch in that both are composed of chains of glucose or glucose-derived units, but chitin has a different structural arrangement.
What is glycogen and where is it typically stored in the body?
-Glycogen is a form of polysaccharide that serves as the primary storage form of glucose in animals, including humans. It is typically stored in the liver and muscles to provide a readily available energy source.
What is cellulose and where can it be commonly found?
-Cellulose is a polysaccharide that is a major component of the cell walls of plants. It can be commonly found in paper, wood, and cotton, which is one of the purest forms of cellulose.
What is the structural difference between starch and cellulose?
-The structural difference between starch and cellulose lies in the orientation of the glucose molecules in their chains. In starch, the glucose molecules are linked in the same orientation as in the original glucose molecule, while in cellulose, the glucose units are flipped over, creating a different bonding pattern.
What are hydrogen bonds and how do they contribute to the structure of cellulose?
-Hydrogen bonds are a type of chemical bond that occurs between a hydrogen atom covalently bonded to an electronegative atom and an electronegative atom in a different molecule. In cellulose, hydrogen bonds form between the oxygen atoms of one glucose strand and the hydrogen atoms of another, contributing to its strong and rigid structure.
What is hydrolysis and how does it relate to breaking down polysaccharides?
-Hydrolysis is a chemical process that involves the breaking of a bond in a molecule using water. In the context of polysaccharides, hydrolysis is the process by which these large carbohydrate chains are broken down into their constituent monosaccharide units, such as glucose, through the addition of water.
Can you describe the mechanism of hydrolysis in breaking the bond between glucose molecules in a polysaccharide?
-The mechanism of hydrolysis involves a water molecule interacting with the bond between glucose units in a polysaccharide. An oxygen atom in the water molecule can grab a hydrogen proton from a nearby hydronium molecule, forming a covalent bond and becoming positively charged. This allows another water molecule to form a bond with the carbon atom, leading to the breaking of the original bond and the release of individual monosaccharide units.
How is the process of hydrolysis important in biology?
-Hydrolysis is crucial in biology as it allows organisms to break down complex carbohydrates like starch, glycogen, and cellulose into simpler monosaccharides, such as glucose. This process is essential for energy production and metabolic processes within cells.