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Carbs, fats and proteins. Biology Ms. Williams 2013-2014. Life. All living things are… . Life. All living things are… Made up of cell(s) Respond to the environment Adapt to the environment Reproduce Grow and develop Require and use energy. Require and Use Energy. Food sources.
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Carbs, fats and proteins Biology Ms. Williams 2013-2014
Life • All living things are…
Life • All living things are… • Made up of cell(s) • Respond to the environment • Adapt to the environment • Reproduce • Grow and develop • Require and use energy
Require and Use Energy • Food sources
Require and Use Energy • Food sources • Carbohydrates • Lipids (fats) • Proteins
Carbohydrates Combination of water molecules and carbon Always has this ratio: 1C : 2H : 1O (CH2O)n C6H12O6 = Glucose! Isomers Same chemical formula, different shape
Carbohydrates:Glucose Simple sugar n=6 C6H12O6 Long chain or ring
α- D – glucose β- D- glucose Glucose Note the different placement of the hydroxyl group (-OH) 36% alpha vs 64% beta
Dehydration Synthesis Two monosaccharides to one disaccharide. (Two monomers to one polymer). Water is released.
Hydrolysis Addition of water to break oxygen bond of disaccharide/ polymer to create two monosaccharides/ monomers.
Carbohydrates: Glucose Simple sugar n=6 C6H12O6 Long chain or ring
Carbohydrates:Fructose Simple sugar n=6 C6H12O6 Long chain or ring form
Carbohydrates:Galactose Simple sugar n=6 C6H12O6 Long chain or ring (revised ring structure)
Carbohydrates:Lactose Dehydration synthesis of Glucose and Galactose Found in milk Inability to break down lactose = lactose intolerance People who can break down lactose are the weirdos.
Carbohydrates:Sucrose Dehydration synthesis of Glucose and Fructose Table sugar
Carbohydrates: Maltose Dehydration synthesis of Glucose and Glucose Malt sugar/syrup Least common sugar found in nature
Polysaccharides • Long chains of monosaccarides • Energy storage • Structural support
Lipids • Fats, waxes, oils, steroids • Triglycerides • Phospholipids • Don’t dissolve well in water
Triglycerides • Polymers made of… • A three carbon molecule Glyceride • Three fatty acids – long chains of carbon
Fatty acids Long chains of carbon Can release H+ in solution, weak acids Saturated or Unsaturated Triglycerides
Fatty Acids Saturated Unsaturated One or more carbons share a double bond and share fewer hydrogen atoms All carbons have single bonds, and are filled to capacity with hydrogen atoms
Fatty Acids Saturated Unsaturated One or more carbons share a double bond and share fewer hydrogen atoms Healthy All carbons have single bonds, and are filled to capacity with hydrogen atoms Less Healthy
Fatty Acids Saturated: Butter, Animal fats Higher melting temperature Unsaturated: Nuts, avocado, fish, veg. oil Lower melting temperature
Phospholipids • Similar to triglycerides, but… • Have a phosphate group and a polar group in place of the 3rd fatty acid (only two tails) • Polar = one part has small neg. charge, other pos. • Ex. Water • Non-polar = No separation of charge • Ex. Fats
Phospholipids • Hydrophilic, polar heads – “water loving” • Soluble in water • Hydrophobic, non-polar tails – “water fearing” • Non-soluble in water
Proteins • Important biological compounds • Enzymes: chemical reactions • Structure: claws, hooves, hair, skin, muscles • Chemical messengers: hormones • Protection: antibodies • Transport: bind and carry atoms within cells and throughout the body
Proteins • Long chains of amino acids • Form sheets, helixes, loops • Operate as molecular machines • Polymers • “polypeptides” • Formed from dehydration synthesis
Amino Acids • Combine to make proteins • Perform many biological processes: • Grow, break down food, repair tissues • Composition • Common group • Side group • This differentiates the amino acid • 21 biologically important
Amino Acids • Classified into 3 groups • Essential amino acids • Cannot be made by the body – have to be eaten (9) • Nonessential amino acids • Produced by body (4) • Conditional amino acids • Usually not essential, except for times of stress – illness (8)
Differ in polarity, charge, shape • If we don’t consume the essential amino acids, they will break down proteins (muscles, etc.)
Protein Structure • Primary – amino acid chain (one dimensional)
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional)
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional)
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional)
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional) • Tertiary – foldedαhelices and/or βsheets (three dimensional)
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional) • Tertiary – foldedαhelices and/or βsheets (three dimensional) • Quaternary – more than one amino acid chain folded in αhelices or βsheets
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional) • Tertiary – foldedαhelices and/or βsheets (three dimensional) • Quaternary – more than one amino acid chain folded in αhelices or βsheets
Protein Structure • Primary – amino acid chain (one dimensional) • Secondary – αhelix or βsheet (two dimensional) • Tertiary – foldedαhelices and/or βsheets (three dimensional) • Quaternary – more than one amino acid chain folded in αhelices or βsheets