Overview: Carbon: The Backbone of Life
Figure 4.1
Concept 4.1: Organic chemistry is the study of carbon compounds
Organic Molecules and the Origin of Life on Earth
Figure 4.2
Concept 4.2: Carbon atoms can form diverse molecules by bonding to four other atoms
The Formation of Bonds with Carbon
Figure 4.3
Figure 4.4
Figure 4.UN01
Molecular Diversity Arising from Carbon Skeleton Variation
Figure 4.5
Figure 4.5a
Figure 4.5b
Figure 4.5c
Figure 4.5d
Hydrocarbons
Figure 4.6
Figure 4.6a
Isomers
Figure 4.7
Figure 4.7a
Figure 4.7b
Figure 4.7c
Figure 4.8
Concept 4.3: A few chemical groups are key to the functioning of biological molecules
The Chemical Groups Most Important in the Processes of Life
Figure 4.UN02
Figure 4.9-a
Figure 4.9-b
Figure 4.9a
Figure 4.9b
Figure 4.9c
Figure 4.9d
Figure 4.9e
Figure 4.9f
Figure 4.9g
ATP: An Important Source of Energy for Cellular Processes
Figure 4.UN03
Figure 4. UN04
The Chemical Elements of Life: A Review
Figure 4. UN05
Figure 4. UN07
Figure 4. UN08
Figure 4. UN09
Figure 4. UN10
Figure 4. UN11
Figure 4. UN12
Figure 4. UN13
Figure 4. UN14
Figure 4. UN15
6.23M
Categories: biologybiology chemistrychemistry

Carbon and the molecular diversity of life. (Chapter 4)

1.

LECTURE PRESENTATIONS
For CAMPBELL BIOLOGY, NINTH EDITION
Jane B. Reece, Lisa A. Urry, Michael L. Cain, Steven A. Wasserman, Peter V. Minorsky, Robert B. Jackson
Chapter 4
Carbon and the Molecular
Diversity of Life
Lectures by
Erin Barley
Kathleen Fitzpatrick
© 2011 Pearson Education, Inc.

2. Overview: Carbon: The Backbone of Life

• Living organisms consist mostly of carbon-based
compounds
• Carbon is unparalleled in its ability to form large,
complex, and diverse molecules
• Proteins, DNA, carbohydrates, and other
molecules that distinguish living matter are all
composed of carbon compounds
© 2011 Pearson Education, Inc.

3. Figure 4.1

4. Concept 4.1: Organic chemistry is the study of carbon compounds

• Organic chemistry is the study of compounds
that contain carbon
• Organic compounds range from simple
molecules to colossal ones
• Most organic compounds contain hydrogen
atoms in addition to carbon atoms
© 2011 Pearson Education, Inc.

5.

• Vitalism, the idea that organic compounds
arise only in organisms, was disproved when
chemists synthesized these compounds
• Mechanism is the view that all natural
phenomena are governed by physical and
chemical laws
© 2011 Pearson Education, Inc.

6. Organic Molecules and the Origin of Life on Earth

• Stanley Miller’s classic experiment
demonstrated the abiotic synthesis of
organic compounds
• Experiments support the idea that abiotic
synthesis of organic compounds, perhaps
near volcanoes, could have been a stage in
the origin of life
© 2011 Pearson Education, Inc.

7. Figure 4.2

EXPERIMENT
“Atmosphere”
Water vapor
CH4
Electrode
NH
3
H2
Condenser
Cooled “rain”
containing
organic
molecules
H2O
“sea”
Sample for chemical analysis
Cold
water

8. Concept 4.2: Carbon atoms can form diverse molecules by bonding to four other atoms

• Electron configuration is the key to an atom’s
characteristics
• Electron configuration determines the kinds
and number of bonds an atom will form with
other atoms
© 2011 Pearson Education, Inc.

9. The Formation of Bonds with Carbon

• With four valence electrons, carbon can form
four covalent bonds with a variety of atoms
• This ability makes large, complex molecules
possible
• In molecules with multiple carbons, each carbon
bonded to four other atoms has a tetrahedral
shape
• However, when two carbon atoms are joined by
a double bond, the atoms joined to the carbons
are in the same plane as the carbons
© 2011 Pearson Education, Inc.

10. Figure 4.3

Name and
Comment
Molecular
Formula
(a) Methane
CH4
(b) Ethane
C2H6
(c) Ethene
(ethylene)
C2H4
Structural
Formula
Ball-andStick Model
Space-Filling
Model

11.

• The electron configuration of carbon gives it
covalent compatibility with many different
elements
• The valences of carbon and its most frequent
partners (hydrogen, oxygen, and nitrogen) are
the “building code” that governs the
architecture of living molecules
© 2011 Pearson Education, Inc.

12. Figure 4.4

Hydrogen
(valence 1)
Oxygen
(valence 2)
Nitrogen
(valence 3)
Carbon
(valence 4)

13.

• Carbon atoms can partner with atoms other than
hydrogen; for example:
– Carbon dioxide: CO2
– Urea: CO(NH2)2
© 2011 Pearson Education, Inc.

14. Figure 4.UN01

Urea

15. Molecular Diversity Arising from Carbon Skeleton Variation

• Carbon chains form the skeletons of most
organic molecules
• Carbon chains vary in length and shape
© 2011 Pearson Education, Inc.

16.

Animation: Carbon Skeletons
Right-click slide/select “Play”
© 2011 Pearson Education, Inc.

17. Figure 4.5

(c) Double bond position
(a) Length
Ethane
Propane
2-Butene
(d) Presence of rings
(b) Branching
Butane
1-Butene
2-Methylpropane
(isobutane)
Cyclohexane
Benzene

18. Figure 4.5a

(a) Length
Ethane
Propane

19. Figure 4.5b

(b) Branching
Butane
2-Methylpropane
(commonly called isobutane)

20. Figure 4.5c

(c) Double bond position
1-Butene
2-Butene

21. Figure 4.5d

(d) Presence of rings
Cyclohexane
Benzene

22. Hydrocarbons

• Hydrocarbons are organic molecules
consisting of only carbon and hydrogen
• Many organic molecules, such as fats, have
hydrocarbon components
• Hydrocarbons can undergo reactions that
release a large amount of energy
© 2011 Pearson Education, Inc.

23. Figure 4.6

Nucleus
Fat droplets
10 m
(a) Part of a human adipose cell
(b) A fat molecule

24. Figure 4.6a

Nucleus
Fat droplets
10 m

25. Isomers

• Isomers are compounds with the same
molecular formula but different structures and
properties
– Structural isomers have different covalent
arrangements of their atoms
– Cis-trans isomers have the same covalent
bonds but differ in spatial arrangements
– Enantiomers are isomers that are mirror
images of each other
© 2011 Pearson Education, Inc.

26.

Animation: Isomers
Right-click slide / select “Play”
© 2011 Pearson Education, Inc.

27. Figure 4.7

(a) Structural isomers
(b) Cis-trans isomers
cis isomer: The two Xs
are on the same side.
trans isomer: The two Xs
are on opposite sides.
(c) Enantiomers
CO2H
CO2H
H
NH2
CH3
L isomer
NH2
H
CH3
D isomer

28. Figure 4.7a

(a) Structural isomers

29. Figure 4.7b

(b) Cis-trans isomers
cis isomer: The two Xs
are on the same side.
trans isomer: The two Xs
are on opposite sides.

30. Figure 4.7c

(c) Enantiomers
CO2H
H
CO2H
NH2
CH3
L isomer
NH2
H
CH3
D isomer

31.

• Enantiomers are important in the
pharmaceutical industry
• Two enantiomers of a drug may have different
effects
• Usually only one isomer is biologically active
• Differing effects of enantiomers demonstrate
that organisms are sensitive to even subtle
variations in molecules
© 2011 Pearson Education, Inc.

32.

Animation: L-Dopa
Right-click slide / select “Play”
© 2011 Pearson Education, Inc.

33. Figure 4.8

Drug
Condition
Ibuprofen
Pain;
inflammation
Albuterol
Effective
Enantiomer
Ineffective
Enantiomer
S-Ibuprofen
R-Ibuprofen
R-Albuterol
S-Albuterol
Asthma

34. Concept 4.3: A few chemical groups are key to the functioning of biological molecules

• Distinctive properties of organic molecules
depend on the carbon skeleton and on the
molecular components attached to it
• A number of characteristic groups can
replace the hydrogens attached to skeletons
of organic molecules
© 2011 Pearson Education, Inc.

35. The Chemical Groups Most Important in the Processes of Life

• Functional groups are the components of
organic molecules that are most commonly
involved in chemical reactions
• The number and arrangement of functional
groups give each molecule its unique
properties
© 2011 Pearson Education, Inc.

36. Figure 4.UN02

Estradiol
Testosterone

37.

• The seven functional groups that are most
important in the chemistry of life:







Hydroxyl group
Carbonyl group
Carboxyl group
Amino group
Sulfhydryl group
Phosphate group
Methyl group
© 2011 Pearson Education, Inc.

38. Figure 4.9-a

CHEMICAL
GROUP
Hydroxyl
Carbonyl
Carboxyl
STRUCTURE
(may be written HO—)
NAME OF
COMPOUND
Alcohols (Their specific names
usually end in -ol.)
Ketones if the carbonyl group is
within a carbon skeleton
Carboxylic acids, or organic acids
Aldehydes if the carbonyl group
is at the end of the carbon skeleton
EXAMPLE
Ethanol
Acetone
Acetic acid
Propanal
FUNCTIONAL
PROPERTIES
• Is polar as a result of the
electrons spending more time
near the electronegative oxygen
atom.
• Can form hydrogen bonds with
water molecules, helping dissolve
organic compounds such as
sugars.
• A ketone and an aldehyde may be
structural isomers with different
properties, as is the case for
acetone and propanal.
• Ketone and aldehyde groups are
also found in sugars, giving rise
to two major groups of sugars:
ketoses (containing ketone
groups) and aldoses (containing
aldehyde groups).
• Acts as an acid; can donate an
H+ because the covalent bond
between oxygen and hydrogen
is so polar:
Nonionized
Ionized
• Found in cells in the ionized form
with a charge of 1 and called a
carboxylate ion.

39. Figure 4.9-b

Amino
Sulfhydryl
Phosphate
Methyl
(may be
written HS—)
Amines
Organic phosphates
Thiols
Cysteine
Glycine
• Acts as a base; can
pick up an H+ from the
surrounding solution
(water, in living
organisms):
Nonionized
Ionized
• Found in cells in the
ionized form with a
charge of 1+.
Glycerol phosphate
• Two sulfhydryl groups can
react, forming a covalent
bond. This “cross-linking”
helps stabilize protein
structure.
• Contributes negative charge to
the molecule of which it is a part
(2– when at the end of a molecule,
as above; 1– when located
internally in a chain of
phosphates).
• Cross-linking of cysteines
in hair proteins maintains
the curliness or straightness
of hair. Straight hair can be
“permanently” curled by
shaping it around curlers
and then breaking and
re-forming the cross-linking
bonds.
• Molecules containing phosphate
groups have the potential to react
with water, releasing energy.
Methylated compounds
5-Methyl cytidine
• Addition of a methyl group
to DNA, or to molecules
bound to DNA, affects the
expression of genes.
• Arrangement of methyl
groups in male and female
sex hormones affects their
shape and function.

40. Figure 4.9a

Hydroxyl
STRUCTURE
(may be written
HO—)
EXAMPLE
Ethanol
Alcohols
(Their specific
names usually
end in -ol.)
NAME OF
COMPOUND
• Is polar as a result
of the electrons
spending more
time near the
electronegative
oxygen atom.
FUNCTIONAL
PROPERTIES
• Can form hydrogen
bonds with water
molecules, helping
dissolve organic
compounds such
as sugars.

41. Figure 4.9b

Carbonyl
STRUCTURE
Ketones if the carbonyl
group is within a
carbon skeleton
NAME OF
COMPOUND
Aldehydes if the carbonyl
group is at the end of the
carbon skeleton
EXAMPLE
Acetone
Propanal
• A ketone and an
aldehyde may be
structural isomers
with different properties,
as is the case for
acetone and propanal.
• Ketone and aldehyde
groups are also found
in sugars, giving rise
to two major groups
of sugars: ketoses
(containing ketone
groups) and aldoses
(containing aldehyde
groups).
FUNCTIONAL
PROPERTIES

42. Figure 4.9c

Carboxyl
STRUCTURE
Carboxylic acids, or organic
acids
NAME OF
COMPOUND
EXAMPLE
• Acts as an acid; can
FUNCTIONAL
PROPERTIES
donate an H because the
covalent bond between
oxygen and hydrogen is so
polar:
+
Acetic acid
Nonionized
Ionized
• Found in cells in the ionized
form with a charge of 1– and
called a carboxylate ion.

43. Figure 4.9d

Amino
STRUCTURE
Amines
NAME OF
COMPOUND
EXAMPLE
FUNCTIONAL
PROPERTIES
Acts as a base; can
pick up an H+ from the
surrounding solution
(water, in living
organisms):
Glycine
Nonionized
Ionized
Found in cells in the
ionized form with a
charge of 1 .

44. Figure 4.9e

Sulfhydryl
STRUCTURE
Thiols
NAME OF
COMPOUND
Two sulfhydryl groups can
react, forming a covalent
bond. This “cross-linking”
helps stabilize protein
structure.
FUNCTIONAL
PROPERTIES
Cross-linking of cysteines
in hair proteins maintains
the curliness or straightness
of hair. Straight hair can be
“permanently” curled by
shaping it around curlers
and then breaking and
re-forming the cross-linking
bonds.
(may be
written HS—)
EXAMPLE
Cysteine

45. Figure 4.9f

Phosphate
STRUCTURE
Organic phosphates
EXAMPLE
FUNCTIONAL
Contributes negative
charge to the molecule PROPERTIES
of which it is a part
(2– when at the end of
a molecule, as at left;
1– when located
internally in a chain of
phosphates).
Molecules containing
phosphate groups have
the potential to react
with water, releasing
energy.
Glycerol phosphate
NAME OF
COMPOUND

46. Figure 4.9g

Methyl
STRUCTURE
Methylated compounds
EXAMPLE
Addition of a methyl group FUNCTIONAL
PROPERTIES
to DNA, or to molecules
bound to DNA, affects the
expression of genes.
Arrangement of methyl
groups in male and female
sex hormones affects their
shape and function.
5-Methyl cytidine
NAME OF
COMPOUND

47. ATP: An Important Source of Energy for Cellular Processes

• One phosphate molecule, adenosine
triphosphate (ATP), is the primary energytransferring molecule in the cell
• ATP consists of an organic molecule called
adenosine attached to a string of three
phosphate groups
© 2011 Pearson Education, Inc.

48. Figure 4.UN03

a.
b.

49. Figure 4. UN04

Adenosine

50. The Chemical Elements of Life: A Review

• The versatility of carbon makes possible the
great diversity of organic molecules
• Variation at the molecular level lies at the
foundation of all biological diversity
© 2011 Pearson Education, Inc.

51. Figure 4. UN05

Reacts
with H2O
Adenosine
Adenosine
ATP
Inorganic
phosphate
ADP
Energy

52. Figure 4. UN07

53. Figure 4. UN08

54. Figure 4. UN09

55. Figure 4. UN10

56. Figure 4. UN11

57. Figure 4. UN12

58. Figure 4. UN13

59. Figure 4. UN14

60. Figure 4. UN15

English     Русский Rules