Would YOU Eat This? And why is it important? What is food? On the left side of your journal, describe your thoughts of the video. Answer the questions: What is food? And why is it important?
Biomolecules
All living things need energy and nutrients All living things need energy and nutrients. Most organisms get their energy and nutrients from their FOOD in the form of biomolecules. Proteins, nucleic acids, carbohydrates and lipids are the 4 main classes of biomolecules.
Nucleic acids Proteins Carbohydrates 3 of the 4 classes of biomolecules are classified as polymers. These are long molecules are made of very similar, repeating monomers. Nucleic acids Proteins Carbohydrates
Understanding the Vocabulary Photo by Toni Lozano When we say “polymer” we are referring to the whole molecule. What would you call the entire object above? It is a chain. I would say that chains are like polymers.
It is a link. I would say that links are like monomers. Polymer: chain Monomer: link Photo by Toni Lozano When we say “monomer” we are referring to the individual piece that keeps repeating. What would you call the individual pieces of a chain? It is a link. I would say that links are like monomers.
The entire chain is the polymer, and each monkey is a monomer. In this picture, what would you say is the polymer, and what would be the monomers? The entire chain is the polymer, and each monkey is a monomer.
Important Vocabulary: 1. All of the biomolecules can be broken apart or digested to obtain their building blocks and the energy inside of them. 2. Biomolecules can also be built or synthesized by the cells to complete certain tasks and store energy for later use.
Synthesizing & Digesting: Two basic reactions: 1) Dehydration synthesis Dehydration – water lost Synthesis - build = removing a water molecule to build a polymer!!
Synthesizing & Digesting: 2) Hydrolysis Hydro – water Lysis – break apart = Using water to break apart polymers! DIGESTION!!!!!!!!
With a partner, define a monomer and a polymer… What is another everyday example you can think of that have monomers and polymers?
Carbohydrates are made of sugars This is a simple sugar This large molecule is a complex carbohydrate.
Carbohydrates are also known as saccharides. monosaccharide disaccharide polysaccharide
Carbohydrates provide ENERGY! Sugars are produced by plants during photosynthesis, and they are the primary source of energy for most organisms. Carbohydrates provide ENERGY!
Carbohydrates are also used in the cell walls of plants and other organisms. When sugars are placed together into complex carbohydrates like cellulose they become very strong and rigid. cell wall Cellulose
Lipids Types of Lipids Lipids are the group of biomolecules that contains fats, cholesterols, and phospholipids. Diagrams by Eoin Fahy
Fats are a primary example of lipids. Fats are made of a glycerol molecule attached to three fatty acids.
Lipids can also be used to store large amounts of energy. Gram for gram, lipids contain MORE ENERGY than carbohydrates. This is why your body stores its extra energy in the form of fat.
Lipids Lipids are also the primary component of all of the cell’s membranes. Membranes are made out of phospholipid molecules. Phospholipid
With a partner, discuss the following question: What are two ways that carbs and lipids are alike?
Nucleic acids are made of nucleotides This is a nucleotide This large molecule is a nucleic acid.
Every nucleotide has 3 basic parts: 1. The phosphate group 2. A sugar named deoxyribose 3. One of the 4 nitrogen bases
The primary function of nucleic acids is to store genetic information used to make proteins. DNA & RNA are the two main types of nucleic acids. The NA in DNA and RNA stands for Nucleic Acid! RNA
1 glucose is placed in to 36 ATP molecules. Nucleotides are also used to distribute energy more efficiently. The energy from 1 glucose is placed in to 36 ATP molecules. 36 ATP 1 Glucose The ATP molecules can deliver smaller amounts of energy so that energy is not wasted!
ATP stands for Adenosine Triphosphate, ATP is a nucleotide. Instead of 1 phosphate group, there are 3 phosphate groups. The bonds between these extra phosphate groups is where the energy is stored. ATP stands for Adenosine Triphosphate, but you can remember that it gives cells All The Power!
This large molecule is a protein. Proteins are made of amino acids This is an amino acid This large molecule is a protein.
Proteins are also known as polypeptides. This is because the bond that holds amino acids together in a protein is called a peptide bond. Peptide Bonds
Proteins Proteins are the most diverse groups of biomolecule, and they perform the largest variety of functions in the cells. IMPORTANT: The order of the amino acids determines the shape of protein Shape determines FUNCTION!
Proteins can be used to transport molecules through membranes, attack invading germs, carry oxygen through the blood and send signals through the body! Image by Gareth White Hemoglobin Insulin (Hormone) Enzymes Immunoglobin (Antibodies)
Structure of Proteins Primary Structure is just the specific order of amino acids in the chain. Secondary Structures are either a helix or a pleated sheet formed form hydrogen bonds reacting between the amino acids.
Structure of Proteins Tertiary Structure occurs because of attractions between the alpha helices and pleated sheets. Quaternary Structure is a protein consisting of more than one amino acid chain.
With a partner, discuss the following question: How are carbohydrates and nucleic acids related?
Enzyme digesting a molecule Possibly the most important type of proteins are called enzymes. Enzymes are found in every cell, and they speed up chemical reactions inside the cell. Enzymes Enzyme digesting a molecule
Enzymes 1. Enzymes can break apart or digest large molecules into smaller pieces. 2. Enzymes can also synthesize large molecules by putting small pieces together.
Important Fact Proteins All four classes of biomolecules are considered organic compounds. This is because they are all based on the element carbon. Carbohydrates Lipids Nucleic Acids
With a partner, discuss the following question: How do we obtain carbon from the carbon cycle?