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The Chemistry of Life Macromolecules

The Chemistry of Life Macromolecules. Macromolecules or organic compounds make up the body. The backbone of these compounds is carbon; from here carbon-containing compounds. have a core based around carbon the core has attached groups of atoms called functional groups

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The Chemistry of Life Macromolecules

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  1. The Chemistry of LifeMacromolecules • Macromolecules or organic compounds make up the body. • The backbone of these compounds is carbon; from here carbon-containing compounds. • have a core based around carbon • the core has attached groups of atoms called functional groups • the functional groups confer specific chemical properties on the organic molecules

  2. Polymers Are Built of Monomers • There are four types of macromolecules: • Carbohydrates • Lipids • Proteins • Nucleic acids • Large macromolecules are actually assembled from many similar small components, called monomers • the assembled chain of monomers is known as a polymer

  3. Carbohydrates • Carbohydrates are monomers that make up the structural framework of cells and play a critical role in energy storage • a carbohydrate is any molecule that contains the elements C, H, and O in a 1:2:1 ratio • Example: Sugar glucose C6H1206 • the sizes of carbohydrates varies • simple carbohydrates – made up of one or two monomers • complex carbohydrates – made up of polymers

  4. Carbohydrates • Simple carbohydrates are small • monosaccharides consist of only one monomer subunit • an example is the sugar glucose (C6H12O6) • disaccharides consist of two monosaccharides • an example is the sugar sucrose, which is formed by joining together two monosaccharides, glucose and fructose

  5. Carbohydrates • Complex carbohydrates are long polymer chain • the long chains are called polysaccharides • Plants and animals store energy in polysaccharide chains formed from glucose • plants form starch • animals form glycogen

  6. Carbohydrates • Some polysaccharides are structural and resistant to digestion by enzymes • plants form cellulose cell walls • some animals form chitin for exoskeletons

  7. Carbohydrates and their function

  8. Lipids • Lipids – fats and other molecules that are not soluble in water • lipids are non-polar molecules • lipids have many different types • fats • oils • steroids • rubber • waxes • pigments

  9. Lipids • fats have two subunits • fatty acids • glycerol • fatty acids are chains of C and H atoms, known as hydrocarbons • the chain ends in a carboxyl (-COOH) group

  10. Because there are 3 fatty acids attached to a glycerol, another name for a fat is triglyceride

  11. Saturated and unsaturated fats • Fatty acids have different chemical properties due to the number of hydrogens that are attached to the non-carboxyl carbons • if the maximum number of hydrogens are attached, then the fat is said to be saturated • Fat is solid at room temperature • if there are fewer than the maximum attached, then the fat is said to be unsaturated • Oil is liquid at room temperature.

  12. Saturated and unsaturated fats

  13. Lipids • Biological membranes involve lipids • phospholipids make up the two layers of the membrane • cholesterol is embedded within the membrane Lipids are a key component of biological membranes

  14. Proteins • Proteins are complex macromolecules that are polymers of many subunits called amino acids • the covalent bond linking two amino acids together is called a peptide bond • the assembled polymer is called a polypeptide amino acids, polypeptide

  15. The many functions of proteins

  16. Proteins • Amino acids are small molecules with a simple basic structure, a carbon atom to which three groups are added • an amino group (-NH2) • a carboxyl group (-COOH) • a functional group (R) • The functional group gives amino acids their chemical identity • there are 20 different types of amino acids

  17. Proteins • Protein structure is complex • the order of the amino acids that form the polypeptide is important • the sequence of the amino acids affects how the protein folds together • the way that a polypeptide folds to form the protein determines the protein’s function • some proteins are comprised of more than one polypeptide

  18. Proteins • There are four general levels to protein structure • Primary • Secondary • Tertiary • Quaternary

  19. Proteins • Primary structure – the sequence of amino acids in the polypeptide chain • This determines all other levels of protein structure Levels of protein structure (circle the primary structure)

  20. Proteins • Secondary structure forms because regions of the polypeptide that are non-polar are forced together • The folded structure may resemble coils, helices, or sheets Levels of protein structure (circle the secondary structure)

  21. Proteins • Tertiary structure – the final 3-D shape of the protein • The final twists and folds that lead to this shape are the result of polarity differences in regions of the polypeptide Levels of protein structure (circle the tertiary structure)

  22. Proteins • Quaternary structure – the spatial arrangement of proteins comprised of more than one polypeptide chain Levels of protein structure (circle the quaternary structure)

  23. Protein • The shape of a protein affects its function • changes to the environment of the protein may cause it to unfold or denature • increased temperature or lower pH affects hydrogen bonding, which is involved in the folding process • a denatured protein is inactive

  24. Nucleic Acids • Nucleic acids are very long polymers that store information • comprised of monomers called nucleotides • each nucleotide has 3 parts • a five-carbon sugar • a phosphate group • an organic nitrogen-containing base • there are five different types of nucleotides • information is encoded in the nucleic acid by different sequences of these nucleotides

  25. Nucleic Acids • There are two types of nucleic acids • Deoxyribonucleic acid (DNA) • Ribonucleic acid (RNA) • RNA is similar to DNA except that • it uses uracil instead of thymine • it is comprised of just one strand • it has a ribose sugar

  26. Nucleic Acids • The structure of DNA is a double helix because • there are only two base pairs possible • Adenosine (A) pairs with thymine (T) • Cytosine (C) pairs with Guanine (G) • the bond holding together a base pair is hydrogen bond • a sugar-phosphate backbone comprised of phosphodiester bonds gives support

  27. The DNA double helix

  28. Nucleic Acids • The structure of DNA helps it to function (information storage) • the hydrogen bonds of the base pairs can be easily broken to unzip the DNA so that information can be copied • each strand of DNA is a mirror image so the DNA contains two copies of the information • having two copies means that the information can be accurately copied and passed to the next generation

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