1. 3
Biological Molecules 1

2. Chapter 3 At a Glance
3.1 Why Is Carbon So Important in Biological Molecules?
3.2 How Are Organic Molecules Synthesized?
3.3 What Are Carbohydrates?
3.4 What Are Lipids?
3.5 What Are Proteins?
3.6 What Are Nucleotides and Nucleic Acids?

3. 3.1 Why Is Carbon So Important in Biological Molecules?
Organic refers to molecules containing a carbon skeleton bonded to hydrogen atoms
Inorganic refers to carbon dioxide and all molecules without carbon

4. 3.1 Why Is Carbon So Important in Biological Molecules?
The unique bonding properties of carbon are key to the complexity of organic molecules
The carbon atom is versatile because it has four electrons in an outermost shell that can accommodate eight electrons
Therefore, a carbon atom can become stable by forming up to four bonds (single, double, or triple)
As a result, organic molecules can assume complex shapes, including branched chains, rings, sheets, and helices

5. Figure 3-1 Bonding patterns
hydrogen H
carbon C C C C
nitrogen N N N
oxygen O O 5

6. 3.1 Why Is Carbon So Important in Biological Molecules?
The unique bonding properties of carbon are key to the complexity of organic molecules (continued)
Functional groups in organic molecules determine the characteristics and chemical reactivity of the molecules
Functional groups are less stable than the carbon backbone and are more likely to participate in chemical reactions

7. Table 3-1 7

8. 3.2 How Are Organic Molecules Synthesized?
Small organic molecules (called monomers) are joined to form longer molecules (called polymers)
Biomolecules are joined or broken through dehydration synthesis or hydrolysis

9. 3.2 How Are Organic Molecules Synthesized?
Biological polymers are formed by removing water and split apart by adding water
Monomers are joined together through dehydration synthesis, at the site where an H and an OH are removed, resulting in the loss of a water molecule (H2O)
The openings in the outer electron shells of the two subunits are filled when the two subunits share electrons, creating a covalent bond

10. Figure 3-2 Dehydration synthesis10

11. 3.2 How Are Organic Molecules Synthesized?
Biological polymers are formed by removing water and split apart by adding water (continued)
Polymers are broken apart through hydrolysis (“water cutting”)
Water is broken into H and OH and is used to break the bond between monomers

12. Animation: Dehydration Synthesis and Hydrolysis

13. Figure 3-3 Hydrolysis
hydrolysis 13

14. 3.2 How Are Organic Molecules Synthesized?
Biological polymers are formed by removing water and split apart by adding water (continued)
All biological molecules fall into one of four categories
Carbohydrates
Lipids
Proteins
Nucleotides/nucleic acids

15. Table 3-2 15

16. 3.3 What Are Carbohydrates?
Carbohydrate molecules are composed of C, H, and O in the ratio of 1:2:1
If a carbohydrate consists of just one sugar molecule, it is a monosaccharide
Two linked monosaccharides form a disaccharide
A polymer of many monosaccharides is a polysaccharide
Carbohydrates are important energy sources for most organisms
Most small carbohydrates are water-soluble due to the polar OH functional group

17. 3.3 What Are Carbohydrates?
There are several monosaccharides with slightly different structures
The basic monosaccharide structure is a backbone of 3–7 carbon atoms
Most of the carbon atoms have both a hydrogen (-H) and a hydroxyl group (-OH) attached to them
Most carbohydrates have the approximate chemical formula (CH2O)n where “n” is the number of carbons in the backbone
When dissolved in the cytoplasmic fluid of a cell, the carbon backbone usually forms a ring

18. 3.3 What Are Carbohydrates?
There are several monosaccharides with slightly different structures (continued)
Glucose (C6H12O6) is the most common monosaccharide in living organisms

19. Figure 3-4 Sugar dissolving in water
hydrogen
bond
hydroxyl
group 19

20. Figure 3-5 Depictions of glucose structure6 5 4 3 2 1
Chemical formula
Linear, ball and stick 6 6 5 5 4 1 4 1 3 3 2 2
Ring, ball and stick
Ring, simplified 20

21. 3.3 What Are Carbohydrates?
There are several monosaccharides with slightly different structures (continued)
Additional monosaccharides are
Fructose (“fruit sugar” found in fruits, corn syrup, and honey)
Galactose (“milk sugar” found in lactose)
Ribose and deoxyribose (found in RNA and DNA, respectively)

22. Figure 3-6 Some six-carbon monosaccharides5 5 2 4 1 4 3 3 1 2
fructose
galactose 22

23. Figure 3-7 Some five-carbon monosaccharides5 5 4 1 4 1 3 2 3 2
Note “missing”
oxygen atom
ribose
deoxyribose 23

24. 3.3 What Are Carbohydrates?
Disaccharides consist of two monosaccharides linked by dehydration synthesis
The fate of monosaccharides inside a cell can be
Some are broken down to free their chemical energy
Some are linked together by dehydration synthesis

25. 3.3 What Are Carbohydrates?
Disaccharides consist of two monosaccharides linked by dehydration synthesis (continued)
Disaccharides are two-part sugars
They are used for short-term energy storage
When energy is required, they are broken apart into their monosaccharide subunits by hydrolysis

26. Figure 3-8 Synthesis of a disaccharide
glucose
fructose
sucrose
dehydration
synthesis 26

27. 3.3 What Are Carbohydrates?
Disaccharides consist of two monosaccharides linked by dehydration synthesis (continued)
Examples of disaccharides include
Sucrose (table sugar)  glucose  fructose
Lactose (milk sugar)  glucose  galactose
Maltose (malt sugar)  glucose  glucose

28. 3.3 What Are Carbohydrates?
Polysaccharides are chains of monosaccharides
Storage polysaccharides include
Starch, an energy-storage molecule in plants, formed in roots and seeds
Glycogen, an energy-storage molecule in animals, found in the liver and muscles
Both starch and glycogen are polymers of glucose molecules

29. Figure 3-9 Starch structure and function
starch grains
Potato cells
A starch molecule
Detail of a starch molecule 29

30. 3.3 What Are Carbohydrates?
Polysaccharides are chains of monosaccharides (continued)
Many organisms use polysaccharides as a structural material
Cellulose (a polymer of glucose) is one of the most important structural polysaccharides
It is found in the cell walls of plants
It is indigestible for most animals due to the orientation of the bonds between glucose molecules

31. Animation: Carbohydrate Structure and Function

32. Figure 3-10 Cellulose structure and function
Cellulose is a major
component of wood
A plant cell with
a cell wall
A close-up of
cellulose fibers
in a cell
wall
Hydrogen bonds
cross-linking
cellulose molecules
bundle of
cellulose
molecules
cellulose fiber
Alternating bond
configuration differs
from starch
Detail of a cellulose molecule 32

33. 3.3 What Are Carbohydrates?
Polysaccharides are chains of monosaccharides (continued)
Chitin (a polymer of modified glucose units) is found in
The outer coverings of insects, crabs, and spiders
The cell walls of many fungi

34. Figure 3-11 Chitin structure and function34

35. 3.4 What Are Lipids?
Lipids are a diverse group of molecules that contain regions composed almost entirely of hydrogen and carbon
All lipids contain large chains of nonpolar hydrocarbons
Most lipids are therefore hydrophobic and water insoluble

36. Animation: Lipids

37. Lipids are diverse in structure and serve a variety of functions
3.4 What Are Lipids?
Lipids are diverse in structure and serve a variety of functions
They are used for energy storage
They form waterproof coverings on plant and animal bodies
They serve as the primary component of cellular membranes
Still others are hormones

38. Lipids are classified into three major groups
3.4 What Are Lipids?
Lipids are classified into three major groups
Oils, fats, and waxes
Phospholipids
Steroids containing rings of carbon, hydrogen, and oxygen

39. 3.4 What Are Lipids?
Oils, fats, and waxes are lipids containing only carbon, hydrogen, and oxygen
Oils, fats, and waxes are made of one or more fatty acid subunits

40. 3.4 What Are Lipids?
Oils, fats, and waxes are lipids containing only carbon, hydrogen, and oxygen (continued)
Fats and oils
Are used primarily as energy-storage molecules, containing twice as many calories per gram as carbohydrates and proteins
Are formed by dehydration synthesis
Three fatty acids  glycerol  triglyceride

41. Figure 3-12 Synthesis of a triglyceride
glycerol
fatty acids
triglyceride 41

42. Figure 3-13a Fat
Fat 42

43. 3.4 What Are Lipids?
Oils, fats, and waxes are lipids containing only carbon, hydrogen, and oxygen (continued)
Fats that are solid at room temperature are saturated (the carbon chain has as many hydrogen atoms as possible, and mostly or all C–C bonds); for example, beef fat

44. Figure 3-14a A fat
A fat 44

45. 3.4 What Are Lipids?
Oils, fats, and waxes are lipids containing only carbon, hydrogen, and oxygen (continued)
Fats that are liquid at room temperature are unsaturated (with fewer hydrogen atoms, and many CC bonds); for example, corn oil
Unsaturated trans fats have been linked to heart disease

46. Figure 3-14b An oil
An oil 46

47. 3.4 What Are Lipids?
Oils, fats, and waxes are lipids containing only carbon, hydrogen, and oxygen (continued)
Waxes are highly saturated and solid at room temperature
Waxes form waterproof coatings such as on
Leaves and stems in plants
Fur in mammals
Insect exoskeletons
Waxes are also used to build honeycomb structures

48. Figure 3-13b Wax
Wax 48

49. 3.4 What Are Lipids?
Phospholipids have water-soluble “heads” and water-insoluble “tails”
These form plasma membranes around all cells
Phospholipids consist of two fatty acids  glycerol  a short polar functional group
They have hydrophobic and hydrophilic portions
The polar functional groups form the “head” and are water soluble
The nonpolar fatty acids form the “tails” and are water insoluble

50. Figure 3-15 Phospholipids
variable
functional
group
phosphate
group
polar head
glycerol
backbone
fatty acid tails
(hydrophilic)
(hydrophobic) 50

51. 3.4 What Are Lipids? Steroids contain four fused carbon rings
Steroids are composed of four carbon rings fused together with various functional groups protruding from them
Examples of steroids include cholesterol
Found in the membranes of animal cells
Component of male and female sex hormones
Makes up 2% of human brain
Excessive cholesterol contributes to cardiovascular disease

52. Figure 3-16 Steroids
Estrogen
Cholesterol
Testosterone 52

53. 3.5 What Are Proteins?
Proteins are molecules composed of chains of amino acids
Proteins have a variety of functions
Enzymes are proteins that promote specific chemical reactions
Structural proteins (e.g., elastin) provide support

54. Table 3-3 54

55. Figure 3-17 Structural proteins
Hair
Horn
Silk 55

56. 3.5 What Are Proteins?
Proteins are molecules composed of chains of amino acids (continued)
Proteins are polymers of amino acids joined by peptide bonds
All amino acids have a similar structure
All contain amino and carboxyl groups
All have a variable “R” group
Some R groups are hydrophobic
Some are hydrophilic
Cysteine R groups can form disulfide bonds

57. Figure 3-18 Amino acid structure
variable
group (R)
amino
group
carboxylic
acid group
hydrogen 57

58. Figure 3-19 Amino acid diversity
glutamic acid (glu)
aspartic acid (asp)
Hydrophilic functional groups
phenylalanine (phe)
leucine (leu)
cysteine (cys)
Hydrophobic functional groups
Sulfur-containing
functional group 58

59. 3.5 What Are Proteins? Amino acids are joined by dehydration synthesis
An amino group reacts with a carboxyl group, and water is lost
The covalent bond resulting after the water is lost is a peptide bond, and the resulting chain of two amino acids is called a peptide
Long chains of amino acids are known as polypeptides, or just proteins

60. Figure 3-20 Protein synthesis
dehydration
synthesis
amino acid
amino acid
peptide
water
amino
group
carboxylic
acid group
amino
group
peptide
bond 60

61. 3.5 What Are Proteins?
A protein can have as many as four levels of structure
Primary structure is the sequence of amino acids linked together in a protein
Secondary structure is a helix, or a pleated sheet
Tertiary structure refers to complex foldings of the protein chain held together by disulfide bridges, hydrophobic/hydrophilic interactions, and other bonds
Quaternary structure occurs where multiple protein chains are linked together

62. Animation: Protein Structure

63. Figure 3-21 The four levels of protein structure
Primary structure:
The sequence of amino
acids linked by peptide
bonds
Secondary structure:
Usually maintained by
hydrogen bonds, which
shape this helix
leu
val
heme group
lys
lys
gly
his
hydrogen
bond
ala
lys
val
Quaternary structure:
Individual polypeptides are
linked to one another by
hydrogen bonds or disulfide
bridges
Tertiary structure:
Folding of the helix results
from hydrogen bonds with
surrounding water molecules
and disulfide bridges between
cysteine amino acids
lys
helix
pro 63

64. Figure 3-22 The pleated sheet and the structure of silk protein
hydrogen
bond
stack of pleated sheets
disordered
segment
strand
of silk
Pleated sheet
Structure of silk 64

65. 3.5 What Are Proteins?
The functions of proteins are related to their three-dimensional structures
Precise positioning of amino acid R groups leads to bonds that determine secondary and tertiary structure
Disruption of secondary and tertiary bonds leads to denatured proteins and loss of function

66. 3.6 What Are Nucleotides and Nucleic Acids?
Nucleotides are the monomers of nucleic acid chains and fall into two general classes
Deoxyribose nucleotides
Ribose nucleotides
All nucleotides are made of three parts
Phosphate group
Five-carbon sugar
Nitrogen-containing base

67. Figure 3-23 Deoxyribose nucleotide
phosphate
base
sugar 67

68. 3.6 What Are Nucleotides and Nucleic Acids?
Nucleotides act as energy carriers and intracellular messengers
Adenosine triphosphate (ATP) is a deoxyribose nucleotide with three phosphate functional groups
Ribose nucleotide cyclic adenosine monophosphate (cAMP) acts as a messenger molecule in cells
Electron carriers are those nucleotides (NAD and FAD) transporting energy in the form of high-energy electrons

69. Figure 3-24 The energy-carrier molecule adenosine triphosphate (ATP)69

70. 3.6 What Are Nucleotides and Nucleic Acids?
DNA and RNA, the molecules of heredity, are nucleic acids
Nucleic acids are polymers formed by monomers strung together in long chains by dehydration synthesis

71. 3.6 What Are Nucleotides and Nucleic Acids?
DNA and RNA, the molecules of heredity, are nucleic acids (continued)
There are two types of polymers of nucleic acids
DNA (deoxyribonucleic acid) is found in chromosomes and carries genetic information needed for protein construction
Each DNA molecule consists of two chains of nucleotides that form a double helix linked by hydrogen bonds
RNA (ribonucleic acid) makes copies of DNA and is used directly in the synthesis of proteins

72. Figure 3-25 Deoxyribonucleic acid
hydrogen
bond 72