5.1.3
Triglycerides & Phospholipids
Triglycerides
Triglycerides
Triglycerides are a type of lipid that are mainly used as energy storage molecules.
Formation of triglycerides
Formation of triglycerides
- Triglycerides are formed by the condensation of one molecule of glycerol and three molecules of fatty acid.
- Ester bonds form between the glycerol and the fatty acid chains.
- One water molecule is released per ester bond.
- So, three molecules of water are released per triglyceride formed.
Structure of fatty acids
Structure of fatty acids
- Fatty acids have long 'tails' made of a chain of hydrocarbons with 4-36 carbon atoms.
- The hydrocarbon tail is variable but most fatty acids contain 12-18 carbons.
- Glycerol links to the central carbon atom on fatty acids.
Types of fatty acids
Types of fatty acids
- The three fatty acids in the triglyceride may be similar or dissimilar.
- Fatty acids may be saturated or unsaturated.
- Some fatty acids have names that come from their origin.
- E.g. Palmitic acid is a saturated fatty acid that comes from the palm tree.
Functions of Triglycerides
Functions of Triglycerides
The structures of triglycerides are related to their functions as molecules responsible for storing energy.
Triglycerides in energy release
Triglycerides in energy release
- Chemical energy is stored in the fatty acid hydrocarbon tails.
- So, lots of energy is released when triglycerides are broken down.
Lipids contain lots of energy
Lipids contain lots of energy
- Carbohydrates contain half the amount of energy per gram as lipids do.
Triglycerides repel water
Triglycerides repel water
- Triglycerides are insoluble in water because the fatty acid tails are hydrophobic.
- This means that the cell's water potential is NOT affected by triglycerides.
- This is important because if triglycerides didn't repel water, the water would enter the cell through the process of osmosis. This would make the cells swell up.
Lipid droplets
Lipid droplets
- In cells, the insoluble triglycerides crowd together as droplets because the hydrophobic fatty acid tails face inwards.
Phospholipids
Phospholipids
Phospholipids are a type of lipid that forms a bilayer. They are the main component of cell membranes and are responsible for controlling what goes into and out of cells.
Structure of phospholipids
Structure of phospholipids
- Phospholipids and triglycerides are quite similar. They are both composed of fatty acid chains attached to glycerol.
- The main difference is that one of the three hydrophobic fatty acid tails is replaced by a hydrophilic phosphate group in phospholipids.
- This means that a phospholipid molecule has a hydrophobic and hydrophilic part.
- This kind of molecule is called an amphipathic molecule.
Hydrophobic tail
Hydrophobic tail
- Phospholipids have two fatty acid chains.
- The two fatty acid chains in phospholipids are hydrophobic and cannot interact with water.
- In membranes, the hydrophobic fatty acid tails face inwards in the bilayer.
- This means that water-soluble substances can't easily pass through the membrane.
Hydrophilic head
Hydrophilic head
- The modified phosphate group in phospholipids is hydrophilic and can interact with water.
- In membranes, the hydrophilic phosphate group faces the outside.
1Unity & Diversity - Molecules
1.1Water
1.2DNA Structure & Replication
1.3Transcription & Gene Expression
2Unity & Diversity - Cells
2.1The Origin of Cells
2.2Introduction to Cells
2.3Ultrastructure of Cells
2.4Cell Division
2.5Structure of DNA & RNA
2.6DNA Replication, Transcription & Translation
2.7Cell Respiration
2.8Photosynthesis
2.9Viruses
3Unity & Diversity - Organisms
3.1Diversity of Organisms
3.2Evidence for Evolution
4Unity & Diversity - Ecosystems
4.1Classification
4.3Evolution & Speciation
4.3.1Evidence for Evolution - Fossils & DNA
4.3.2Evidence for Evolution - Anatomy & Geography
4.3.3IB Multiple Choice - Evidence for Evolution
4.3.4Extended Response - DNA & Evolution
4.3.5Populations
4.3.6Mutations, Genetic Drift, & Gene Flow
4.3.7Speciation
4.3.8Rate of Speciation
4.3.9Allopatric & Sympatric Speciation
4.4Conservation of Biodiversity
5Form & Function - Molecules
6Form & Function - Cells
6.1Membranes & Membrane Transport
6.2Organelles & Compartmentalization
6.3Cell Specialization
7Form & Function - Organisms
7.2Transport
7.3Muscle & Motility
8Form & Function - Ecosystems
8.1Species, Communities & Ecosytems
8.3Carbon Cycle
9Interaction & Interdependence - Molecules
9.1Enzymes
9.2Metabolism
9.3Cell Respiration
10Interaction & Interdependence - Cells
10.1Chemical Signalling
10.2Neural Signalling
10.3Adaptation to Environment
10.4Ecological Niches
11Interaction & Interdependence - Organisms
11.1Integration of Body Systems
12Interaction & Interdependence - Ecosystems
12.1Populations & Communities
12.2Transfers of Energy & Matter
13Continuity & Change - Molecules
13.1DNA Replication
13.2Protein Synthesis
14Continuity & Change - Cells
15Continuity & Change - Organisms
15.1Inheritance
15.1.1Non-Nuclear Inheritance
15.1.2Linked Genes
15.1.3IB Multiple Choice - Non-Mendelian Genetics
15.1.4Extended Response - Inheritance
15.1.5Introduction to Non-Mendelian Inheritance
15.1.6Chi-Squared Test
15.1.7End of Topic Quiz - Inheritance
15.1.8Sex-Linked Genes
15.1.9Grade 4-5 (Scientific Practices) - Inheritance
16Continuity & Change - Ecosystems
16.1Natural Selection
16.2Stability & Change
Jump to other topics
1Unity & Diversity - Molecules
1.1Water
1.2DNA Structure & Replication
1.3Transcription & Gene Expression
2Unity & Diversity - Cells
2.1The Origin of Cells
2.2Introduction to Cells
2.3Ultrastructure of Cells
2.4Cell Division
2.5Structure of DNA & RNA
2.6DNA Replication, Transcription & Translation
2.7Cell Respiration
2.8Photosynthesis
2.9Viruses
3Unity & Diversity - Organisms
3.1Diversity of Organisms
3.2Evidence for Evolution
4Unity & Diversity - Ecosystems
4.1Classification
4.3Evolution & Speciation
4.3.1Evidence for Evolution - Fossils & DNA
4.3.2Evidence for Evolution - Anatomy & Geography
4.3.3IB Multiple Choice - Evidence for Evolution
4.3.4Extended Response - DNA & Evolution
4.3.5Populations
4.3.6Mutations, Genetic Drift, & Gene Flow
4.3.7Speciation
4.3.8Rate of Speciation
4.3.9Allopatric & Sympatric Speciation
4.4Conservation of Biodiversity
5Form & Function - Molecules
6Form & Function - Cells
6.1Membranes & Membrane Transport
6.2Organelles & Compartmentalization
6.3Cell Specialization
7Form & Function - Organisms
7.2Transport
7.3Muscle & Motility
8Form & Function - Ecosystems
8.1Species, Communities & Ecosytems
8.3Carbon Cycle
9Interaction & Interdependence - Molecules
9.1Enzymes
9.2Metabolism
9.3Cell Respiration
10Interaction & Interdependence - Cells
10.1Chemical Signalling
10.2Neural Signalling
10.3Adaptation to Environment
10.4Ecological Niches
11Interaction & Interdependence - Organisms
11.1Integration of Body Systems
12Interaction & Interdependence - Ecosystems
12.1Populations & Communities
12.2Transfers of Energy & Matter
13Continuity & Change - Molecules
13.1DNA Replication
13.2Protein Synthesis
14Continuity & Change - Cells
15Continuity & Change - Organisms
15.1Inheritance
15.1.1Non-Nuclear Inheritance
15.1.2Linked Genes
15.1.3IB Multiple Choice - Non-Mendelian Genetics
15.1.4Extended Response - Inheritance
15.1.5Introduction to Non-Mendelian Inheritance
15.1.6Chi-Squared Test
15.1.7End of Topic Quiz - Inheritance
15.1.8Sex-Linked Genes
15.1.9Grade 4-5 (Scientific Practices) - Inheritance
16Continuity & Change - Ecosystems
16.1Natural Selection
16.2Stability & Change
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