Chapter 5 The Structure and Function of Macromolecules - PowerPoint PPT Presentation

1 / 79
About This Presentation
Title:

Chapter 5 The Structure and Function of Macromolecules

Description:

Chapter 5 The Structure and Function of Macromolecules Homework Read chapter 5, 8 Lab report remotes today Chapter 5 Fri. 9/7 Test 1 Week of 9/10 ... – PowerPoint PPT presentation

Number of Views:459
Avg rating:3.0/5.0
Slides: 80
Provided by: Jam147
Category:

less

Transcript and Presenter's Notes

Title: Chapter 5 The Structure and Function of Macromolecules


1
Chapter 5 The Structure and Function of
Macromolecules
2
Focus on
  • Elements in each molecule
  • How molecules are linked and unlinked
  • Examples and functions of each type of molecule

3
Macromolecules
  • Large molecules formed by joining many subunits
    together.
  • Also known as polymers.

4
Monomer
  • A building block of a polymer.

AP Biology
5
Condensation Synthesis or Dehydration Synthesis
  • The chemical reaction that joins monomers into
    polymers.
  • Covalent bonds are formed by the removal of a
    water molecule between the monomers.

6
Hydrolysis
  • Reverse of condensation synthesis.
  • Hydro- water
  • Lysis - to split
  • Breaks polymers into monomers by adding water.

7
(No Transcript)
8
Four Main Types Of Macromolecules
  • Carbohydrates
  • Lipids
  • Protein
  • Nucleic acids

9
For each Macromolecule know the following
  • Elements it contains
  • Monomer units and structures
  • Examples
  • Uses or roles

10
Carbohydrates
  • Used for fuel, building materials, and receptors.
  • Made of C,H,O
  • General formula is CH2O
  • CO ratio is 11

11
Types Of Carbohydrates
  • Monosaccharides
  • Disaccharides
  • Oligosaccharides
  • Polysaccharides

12
Monosaccharides
  • Mono - single
  • Saccharide - sugar
  • Simple sugars.
  • 3 to 7 carbons.
  • Can be in linear or ring forms.

13
Monosaccharides
  • Can be Aldoses or Ketoses depending on the
    location of the carbonyl group.

14
(No Transcript)
15
Examples
  • Glucose
  • Galactose
  • Ribose
  • Fructose

16
- OSE
  • Word ending common for many carbohydrates.

17
Disaccharides
  • Sugar formed by joining two monosaccharides
    through a glycosidic linkage.

18
(No Transcript)
19
Examples
  • Maltose glucose glucose
  • Lactose glucose galactose
  • Sucrose glucose fructose

20
Oligosaccharides
  • 2 - 10 joined simple sugars.
  • Used in cell membranes.

21
Polysaccharides
  • Many joined simple sugars.
  • Used for storage or structure.
  • Examples
  • Starch
  • Cellulose
  • Glycogen

22
(No Transcript)
23
a glucose and b glucose
24
(No Transcript)
25
Starch
  • Made of 1-4 linkages of a glucose.
  • Linkage makes the molecule form a helix.
  • Fuel storage in plants.

26
a glucose
27
Cellulose
  • Made of 1-4 linkages of b glucose.
  • Linkage makes the molecule form a straight line.
  • Used for structure in plant cell walls.

28
b glucose
29
(No Transcript)
30
Comment
  • Most organisms can digest starch (1- 4 a
    linkage), but very few can digest cellulose (1- 4
    b linkage).
  • Another example of the link between structure and
    function.

31
Glycogen
  • Animal starch
  • Similar to starch, but has more 1-6 linkages or
    branches.
  • Found in the liver and muscle cells.

32
Starch
Glycogen
33
Lipids
  • Diverse hydrophobic molecules.
  • Made of C,H,O
  • No general formula.
  • CO ratio is very high in C.

34
Fats and Oils
  • Fats - solid at room temperature.
  • Oils - liquid at room temperature.

35
Fats and Oils
  • Made of two kinds of smaller molecules.
  • Fatty Acids
  • Glycerol

36
Fatty Acids
  • A long carbon chain (12-18 C) with a -COOH (acid)
    on one end and a -CH3 (fat) at the other.

37
Acid
Fat
38
Neutral Fats or Triacylglycerols
  • Three fatty acids joined to one glycerol.
  • Joined by an ester linkage between the -COOH of
    the fatty acid and the -OH of the alcohol.

39
Saturated FatsUnsaturated Fats
  • Saturated - no double bonds.
  • Unsaturated - one or more CC bonds. Can accept
    more Hydrogens.
  • Double bonds cause kinks in the molecules
    shape.

40
(No Transcript)
41
Question
  • Why do fats usually contain saturated fatty acids
    and oils usually contain unsaturated fatty acids?
  • The double bond pushes the molecules apart,
    lowering the density, which lowers the melting
    point.

42
Fats
  • Differ in which fatty acids are used.
  • Used for energy storage, cushions for organs,
    insulation.

43
Question ?
  • Which has more energy, a kg of fat or a kg of
    starch?
  • Fat - there are more C-H bonds which provide more
    energy per mass.

44
Phospholipids
  • Similar to fats, but have only two fatty acids.
  • The third -OH of glycerol is joined to a
    phosphate containing molecule.

45
(No Transcript)
46
Result
  • Phospholipids have a hydrophobic tail, but a
    hydrophilic head.
  • Self-assembles into micells or bilayers, an
    important part of cell membranes.

47
Steroids
  • Lipids with four fused rings.
  • Differ in the functional groups attached to the
    rings.
  • Examples
  • cholesterol
  • sex hormones

48
Proteins
  • The molecular tools of the cell.
  • Made of C,H,O,N, and sometimes S.
  • No general formula.

49
Uses Of Proteins
  • Structure
  • Enzymes
  • Antibodies
  • Transport
  • Movement
  • Receptors
  • Hormones

50
Proteins
  • Polypeptide chains of Amino Acids linked by
    peptide bonds.

51
Amino Acids
  • All have a Carbon with four attachments
  • -COOH (acid)
  • -NH2 (amine)
  • -H
  • -R (some other side group)

52
R groups
  • 20 different kinds
  • Nonpolar - 9 AA
  • Polar - 6 AA
  • Electrically Charged
  • Acidic - 2 AA
  • Basic - 3 AA

53
Amino Acids
54
Amino Acids
55
R groups
  • Contain the S when present in a protein.
  • Cysteine or Cys
  • Methionine or Met
  • The properties of the R groups determine the
    properties of the protein.

56
Polypeptide Chains
  • Formed by dehydration synthesis between the
    carboxyl group of one AA and the amino group of
    the second AA.
  • Produce an backbone of (N-C-C)X

57
(No Transcript)
58
Levels Of Protein Structure
  • Organizing the polypeptide into its 3-D
    functional shape.
  • Primary
  • Secondary
  • Tertiary
  • Quaternary

59
Primary
  • Sequence of amino acids in the
    polypeptide chain.
  • Many different sequences are
    possible with 20
    AAs.

60
(No Transcript)
61
Secondary
  • 3-D structure formed by hydrogen bonding between
    parts of the peptide backbone.
  • Two main secondary structures
  • a helix
  • pleated sheets

62
Tertiary
  • Bonding between the R groups.
  • Examples
  • hydrophobic interactions
  • ionic bonding
  • Disulfide bridges (covalent
    bond)

63
Quaternary
  • When two or more polypeptides unite to form a
    functional protein.
  • Example hemoglobin

64
Is Protein Structure Important?
65
Denaturing Of A Protein
  • Events that cause a protein to lose structure
    (and function).
  • Example
  • pH shifts
  • high salt concentrations
  • heat

66
(No Transcript)
67
AP Biology
Brandi
Crawford County
68
Homework
  • Read chapter 5, 8
  • Lab report remotes today
  • Chapter 5 Fri. 9/7
  • Test 1 Week of 9/10

69
Comment
  • Many other amino acids are possible (change the R
    group)
  • Whole new group of proteins with new properties
    can be made
  • Genetic engineering can use bacteria to make
    these new proteins

70
Nucleic Acids
  • Informational polymers
  • Made of C,H,O,N and P
  • No general formula
  • Examples DNA and RNA

71
Nucleic Acids
  • Polymers of nucleotides
  • Nucleotides have three parts
  • nitrogenous base
  • pentose sugar
  • phosphate

72
Nitrogenous Bases
  • Rings of C and N
  • The N atoms tend to take up H (base).
  • Two types
  • Pyrimidines (single ring)
  • Purines (double rings)

73
Pentose Sugar
  • 5-C sugar
  • Ribose - RNA
  • Deoxyribose DNA
  • RNA and DNA differ in a OH group on the
    2nd carbon.

74
Nucleosides and Nucleotides
  • Nucleoside base sugar
  • Nucleotide base sugar Pi

75
(No Transcript)
76
DNA
  • Deoxyribonucleic Acid.
  • Makes up genes.
  • Genetic information for life.

77
RNA
  • Ribonucleic Acid.
  • Structure and protein synthesis.
  • Genetic information for a few viruses only.

78
DNA and RNA
  • More will be said about DNA and RNA in future
    lessons.

79
Summary
  • Role of hydrolysis and dehydration synthesis
  • For each macromolecule, know the following
  • Elements and monomers
  • Structures
  • Functions
Write a Comment
User Comments (0)
About PowerShow.com