1. THE STRUCTURE AND FUNCTION OF MACROMOLECULES
CH. 5
THE STRUCTURE AND FUNCTION OF MACROMOLECULES

3. Figure 5.1 Building models to study the structure and function of macromolecules

4. I. Polymer Principles A. Most macromolecules are polymers
FOUR MAJOR CLASSES: CARBOHYDRATES, LIPIDS, PROTEINS, AND NUCLEIC ACIDS
MACROMOLECULES: A GIANT MOLECULE OF LIVING MATTER FORMED BY THE JIOINING OF SMALLER MOLECULES
POLYMERS: CHAINS OF IDENTICAL OR SIMILAR BUILDING BLOCKS CALLED MONOMERS
MONOMERS: THE SUBUNIT THAT SERVES AS THE BUILDING BLOCK OF A POLYMER

5. B. A limitless variety of polymers can be built from a small set of monomers
EACH CLASS OF POLYMER IS FORMED FROM A SPECIFIC SET OF MONOMERS

6. Figure 5.2 The synthesis and breakdown of polymers

7. II. Carbohydrates: Fuel and Building Material
A. Sugars, the smallest carbohydrates, serve as fuel and carbon sources
MONOSACCHARIDES ARE THE SIMPLEST CARBOHYDRATES
USES
DIRECTLY FOR FUEL
CONVERTED TO OTHER TYPES OF ORGANIC MOLECULES
MONOMERS FOR POLYMERS

8. Figure 5.3 The structure and classification of some monosaccharides

9. DISSACHARIDES CONSITST OF TWO MONOSACCHARIDES CONNECTED BY GLYSODIC LINKAGE
GLYCOSIDIC LINKAGE: A COVALENT BOND FORMED BETWEEN TWO MONOSACCHARIDES BY A DEHYDRATION REACTION
DEHYDRATION REACTION: REMOVAL OF WATER

10. FIGURE 5.2 THE SYNTHESIS AND BREAKDOWN OF POLYMERS

11. FIGURE 5.4 LINEAR AND RING FORMS OF GLUCOSE

12. Figure 5.5 Examples of disaccharide synthesis

13. Figure 5.5x Glucose monomer and disaccharides
Sucrose
Maltose

14. B. Polysaccharides, the polymers of sugars, have storage and structural roles
THE MONOSACCHARIDE MONOMERS OF POLYSACCHARIDES ARE CONNECTED BY GLYCOSIDIC LINKAGES
EX. STARCH (IN PLANTS) AND GLYCOGEN (IN ANIMALS) ARE STORAGE POLYMERS OF GLUCOSE
EX. CELLULOSE IS A STRUCTURAL POLYMER OF GLUCOSE (IN PLANTS)

15. FIGURE 5.6 STORAGE POLYSACCHARIDES

16. FIGURE 5.8 ARRANGEMENT OF CELLULOSE IN PLANT CELL WALLS

17. III. Lipids: Diverse Hydrophobic Molecules
INTRODUCTION:
LIPIDS ARE THE ONE CLASS OF LARGE BIOLOGICAL MOLECULES THAT DOES NOT INCLUDE POLYMERS.
THE COMPOUNDS CALLED LIPIDS ARE GROUPED TOGETHER BECAUSE THEY SHARE ONE IMPORTANT TRAIT: THEY HAVE LITTLE OR NO AFFINITY FOR WATER.
THE MOST IMPORTANT FAMILIES OF LIPIDS ARE THE FATS, PHOSPHOLIPIDS, AND STEROIDS.
A. Fats store large amounts of energy

18. A. Fats store large amounts of energy
FATS (TRIACYLGLYCEROLS) FORMED BY A GLYCEROL MOLECULE JOINED TO 3 FATTY ACIDS BY DEHYDRATION REACTIONS
SATURATED: HAVE MAX. NUMBER OF HYDROGEN ATOMS
UNSATURATED: HAVE ONE OR MORE DOUBLE BONDS BETWEEN THEIR CARBONS

19. FIGURE 5.10 THE SYNTHESIS AND STRUCTURE OF A FAT, OR TRIACYLGLYCEROL

20. Figure 5.11x Saturated and unsaturated fats and fatty acids: butter and oil

21. Figure 5.11 Examples of saturated and unsaturated fats and fatty acids

22. B. Phospholipids are major components of cell membranes
PHOSPHOLIPIDS HAVE A NEGATIVELY CHARGED PHOSPHATE GROUP
THE “HEAD” OF A PHOSPHOLIPID IS HYDROPHILIC
THE “TAIL” IS HYDROPHOBIC

23. FIGURE 5.12 THE STRUCTURE OF A PHOSPHOLIPID

24. FIGURE 5.13 B- A CROSS SECTION OF A PHOSPHOLIPID BILAYER

25. C. Steroids include cholesterol and certain hormones
STEROIDS HAVE A BASIC STRUCTURE OF FOUR FUSED RINGS OF CARBON ATOMS
CHOLESTEROL IS A MOLECULE FROM WHICH OTHER STEROIDS, INCLUDING THE SEX HORMONES, ARE SYNTHESIZED.
STEROIDS VARY IN THE FUNCTIONAL GROUPS ATTACHED.

26. FIGURE 5.14 CHOLESTEROL: A STEROID

27. IV. Proteins: The Molecular Tools of the Cell
INTRODUCTION
A PROTEIN CONSISTS OF ONE OR MORE POLYPEPTIDE CHAINS FOLDED INTO A SPECIFIC 3-D CONFORMATION

28. Table 5.1 An Overview of Protein Functions

29. Figure 5.0 Spider’s web made of protein

30. A. Polypeptide is a polymer of amino acids connected in a specific sequence
PROTEINS ARE CONSTRUCTED FROM 20 DIFFERENT AMINO ACIDS
EACH AMINO ACID HAS A CHARACTERISTIC SIDE CHAIN (R-GROUP)
THE CARBOXYL AND AMINO GROUPS OF ADJACENT AMINO ACIDS LINK TOGETHER IN PEPTIDE BONDS

31. FIGURE 5.15 THE 20 AMINO ACIDS OF PROTEINS

32. B. A protein’s function depends on its specific conformation
PRIMARY STRUCTURE: UNIQUE SEQUENCE OF AMINO ACIDS
SECONDARY STRUCTURE: FOLDING OR COILING OF THE POLYPEPTIDE INTO REPEATING CONFIGURATIONS
EX. ALPHA-HELIX OR PLEADED SHEET
TERTIARY STRUCTURE: OVERALL 3-D SHAPE OF A POLYPEPTIDE RESULTING FROM THE INTERACTIONS BETWEEN AMINO ACID SIDE CHAINS.
QUARTENARY STRUCTURE: PROTEINS MADE OF MORE THAN ONE POLYPEPTIDE CHAIN

33. FIGURE 5.18 THE PRIMARY STRUCTURE OF PROTEIN

34. FIGURE 5.20 SECONDARY STRUCTURE OF PROTEIN

35. FIGURE 5.22 TERTIARY STRUCTURE W/BONDS

36. FIGURE 5.23 QUARTENARY STRUCTURE OF PROTEIN

37. 5.24 FOUR LEVELS OF PROTEIN STRUCTURE

38. V. Nucleic Acids: Informational Polymers
A. Nucleic acids store and transmit hereditary information
NUCLEIC ACIDS STORE AND TRANSMIT HEREDITARY INFORMATION
DNA STORES INFORMATION FOR THE SYNTHESIS OF SPECIFIC PROTEINS
RNA CARRIES THIS GENETIC INFORMATION TO THE PROTEIN SYNTHESIZING MACHINERY

39. 5.26 PROTEIN SYNTHESIS (INFORMATION FLOW)

40. B. A nucleic acid strand is a polymer of nucleotides
EACH NUCLEOTIDE MONOMER CONSISTS OF A SUGAR COVANTLY BONDED TO A PHOSPHATE GROUP AND TO ONE OF FOUR NITROGENOUS BASES (A,T,C,G)
RNA HAS RIBOSE AS ITS SUGAR, DNA HAS DEOXYRIBOSE
RNA DOES NOT HAVE THYMINE, INSTEAD URACIL AS A NITROGENOUS BASE

41. FIGURE 5.27 THE STRUCTURE OF NUCLEOTIDES AND POLYNEUCLOTIDES

42. C. Inheritance is based on replication of the DNA double helix
DNA IS A HELICAL, DOUBLE STRANDED MACROMOLECULE WITH BASES PROJECTING INTO THE INTERIOR OF THE MOLECULE
DNA STRANDS ARE COMPLEMENTARY (A=T, C=G)
ONE STRAND OF DNA CAN SERVE AS A TEMPLATE FOR THE FORMATION OF THE OTHER
DNA PROVIDES A MECHANISM FOR THE CONTINUITY OF LIFE

43. 5.28 DNA STRUCTURE (DOUBLE HELIX)