Chapter 4 Carbon and the Molecular Diversity of Life PDF

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This document is a PowerPoint presentation about Chapter 4, Carbon and the Molecular Diversity of Life, from the Eighth Edition of Biology by Neil Campbell and Jane Reece. It covers organic chemistry, carbon compounds, and the different functional groups in living organisms. The presentation uses diagrams, text and visuals to describe important figures, concepts, experiments and organic molecules including isotopes, amino acids and the structure of cells.

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Chapter 4

Carbon and the Molecular
Diversity of Life

PowerPoint® Lecture Presentations for

Biology
Eighth Edition
Neil Campbell and Jane Reece

Lectures by Chris Romero, updated by Erin Barley with contributions from Joan Sharp
Copyright © 2008 Pearson Education, Inc., publishing as Pearson Benjamin Cummings
Overview: Carbon: The Backbone of Life

Although cells are 70–95% water, the rest
consists 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

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Fig. 4-1
What properties of carbon underlie its role as the
molecular basis of life?
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

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 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

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 EXPERIMENT
“Atmosphere”
conditions believed to simulate those on the
CH4
Water vapor
Electrode
Can organic molecules form under

NH
3 H2

Condenser
early Earth?

Cooled water
containing Cold
organic water
molecules

H2O
“sea”

Sample for
chemical analysis
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

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The Formation of Bonds with Carbon

With four valence electrons, carbon can form
four covalent bonds with a variety of atoms
This tetravalence 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 molecule has a flat
shape
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Fig. 4-3

The shapes of three simple organic molecules
Molecular Structural Ball-and-Stick Space-Filling
Name Formula Formula Model Model
(a) Methane

(b) Ethane

(c) Ethene
(ethylene)
 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

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Fig. 4-4

Valences of the major elements of
organic molecules

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

H O N C
 Carbon atoms can partner with atoms other
than hydrogen; for example:
– Carbon dioxide: CO2

O=C=O

– Urea: CO(NH2)2

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Fig. 4-UN1

Urea
Molecular Diversity Arising from Carbon Skeleton
Variation
Carbon chains form the skeletons of most
organic molecules
Carbon chains vary in length and shape

Animation: Carbon Skeletons

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Fig. 4-5

Variation in carbon skeletons

Ethane Propane
1-Butene 2-Butene
(a) Length (c) Double bonds

Butane 2-Methylpropane
(commonly called isobutane) Cyclohexane Benzene
(b) Branching (d) Rings
Fig. 4-5a

Variation in carbon skeletons

Ethane Propane

(a) Length
Fig. 4-5b

Variation in carbon skeletons

Butane 2-Methylpropane
(commonly called isobutane)
(b) Branching
Fig. 4-5c

Variation in carbon skeletons

1-Butene 2-Butene
(c) Double bonds
Fig. 4-5d

Variation in carbon skeletons

Cyclohexane Benzene
(d) Rings
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

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Fig. 4-6

The role of hydrocarbons in fats

Fat droplets (stained red)

100 µm
(a) Mammalian adipose cells (b) A fat molecule
Isomers

Isomers are compounds with the same molecular
formula but different structures and properties:
– Structural isomers have different covalent
arrangements of their atoms
– Geometric isomers have the same covalent
arrangements but differ in spatial ‫مكاني‬
arrangements
– Enantiomers are isomers that are mirror
images of each other
Animation: Isomers

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Fig. 4-7

Three types of
isomers

Pentane 2-methyl butane

(a) Structural isomers

cis isomer: The two Xs are trans isomer: The two Xs are
on the same side. on opposite sides.

(b) Geometric isomers

L isomer D isomer
(c) Enantiomers
Fig. 4-7a

Three types of isomers

Pentane 2-methyl butane

(a) Structural isomers
Fig. 4-7b

Three types of isomers

cis isomer: The two Xs are trans isomer: The two Xs are
on the same side. on opposite sides.
(b) Geometric isomers
Fig. 4-7c

Three types of isomers

L isomer D isomer
(c) Enantiomers
 Enantiomers are important in the
pharmaceutical industry
Two enantiomers of a drug may have different
effects
Differing effects of enantiomers demonstrate
that organisms are sensitive to even subtle
variations in molecules

Animation: L-Dopa

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Fig. 4-8

The pharmacological importance of
enantiomers
Effective Ineffective
Drug Condition
Enantiomer Enantiomer

Ibuprofen Pain;
inflammation
S-Ibuprofen R-Ibuprofen

Albuterol Asthma

R-Albuterol S-Albuterol
Concept 4.3: A small number of chemical groups
are key to the functioning of biological molecules
Distinctive properties of organic molecules
depend not only on the carbon skeleton but
also on the molecular components attached
to it
A number of characteristic groups are often
attached to skeletons of organic molecules

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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

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Fig. 4-9

A comparison of chemical groups of female (estradiol) and male
(testosterone) sex hormones

Estradiol

Testosterone
 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
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Fig. 4-10a
CHEMICAL
GROUP Hydroxyl Carbonyl Carboxyl

STRUCTURE

(may be written HO—)

In a hydroxyl group (—OH), a The carbonyl group ( CO) When an oxygen atom is
hydrogen atom is bonded to an consists of a carbon atom double-bonded to a carbon
oxygen atom, which in turn is joined to an oxygen atom by a atom that is also bonded to
Some biologically important

bonded to the carbon skeleton of double bond. an —OH group, the entire
the organic molecule. (Do not assembly of atoms is called
confuse this functional group a carboxyl group (—COOH).
with the hydroxide ion, OH–.)

NAME OF Alcohols (their specific names Ketones if the carbonyl group is Carboxylic acids, or organic
chemical groups

COMPOUND usually end in -ol) within a carbon skeleton acids

Aldehydes if the carbonyl group
is at the end of the carbon
skeleton

EXAMPLE

Ethanol, the alcohol present in Acetone, the simplest ketone Acetic acid, which gives vinegar
alcoholic beverages its sour taste

Propanal, an aldehyde

FUNCTIONAL Is polar as a result of the A ketone and an aldehyde may Has acidic properties
PROPERTIES electrons spending more time be structural isomers with because the covalent bond
near the electronegative different properties, as is the between oxygen and hydrogen
oxygen atom. case for acetone and propanal. is so polar; for example,
Can form hydrogen bonds with These two groups are also
water molecules, helping found in sugars, giving rise to
dissolve organic compounds two major groups of sugars:
such as sugars.
aldoses (containing an
aldehyde) and ketoses
(containing a ketone). Acetic acid Acetate ion

Found in cells in the ionized
form with a charge of 1– and
called a carboxylate ion (here,
specifically, the acetate ion).
Fig. 4-10b
CHEMICAL
GROUP Amino Sulfhydryl Phosphate Methyl

(may be
STRUCTURE written HS—)

The amino group The sulfhydryl group In a phosphate group, a A methyl group consists of a
(—NH2) consists of a consists of a sulfur atom phosphorus atom is bonded to carbon bonded to three
nitrogen atom bonded bonded to an atom of four oxygen atoms; one oxygen hydrogen atoms. The methyl
to two hydrogen atoms hydrogen; resembles a is bonded to the carbon skeleton; group may be attached to a
Some biologically important

and to the carbon hydroxyl group in shape. two oxygens carry negative carbon or to a different atom.
skeleton. charges. The phosphate group
(—OPO32–, abbreviated P) is an
ionized form of a phosphoric acid
group (—OPO3H2; note the two
hydrogens).

NAME OF Amines Thiols Organic phosphates Methylated compounds
chemical groups

COMPOUND

EXAMPLE

Glycine Glycerol phosphate
Because it also has a Cysteine
In addition to taking part in
carboxyl group, glycine many important chemical 5-Methyl cytidine
is both an amine and Cysteine is an important reactions in cells, glycerol
a carboxylic acid; sulfur-containing amino 5-Methyl cytidine is a
compounds with both phosphate provides the
acid. backbone for phospholipids, component of DNA that has
groups are called been modified by addition of
amino acids. the most prevalent molecules in
cell membranes. the methyl group.

FUNCTIONAL Acts as a base; can Two sulfhydryl groups Contributes negative charge Addition of a methyl group
PROPERTIES pick up an H+ from can react, forming a to the molecule of which it is to DNA, or to molecules
the surrounding covalent bond. This a part (2– when at the end of bound to DNA, affects
solution (water, in “cross-linking” helps a molecule; 1– when located expression of genes.
living organisms). stabilize protein internally in a chain of
structure. phosphates). Arrangement of methyl
groups in male and female
Cross-linking of Has the potential to react sex hormones affects
cysteines in hair with water, releasing energy. their shape and function.
proteins maintains the
curliness or straightness
(nonionized) (ionized) of hair. Straight hair can
be “permanently” curled
Ionized, with a by shaping it around
charge of 1+, under curlers, then breaking
cellular conditions. and re-forming the
cross-linking bonds.
Fig. 4-10c

Carboxyl

STRUCTURE NAME OF
Carboxylic acids, or organic COMPOUND
acids

EXAMPLE FUNCTIONAL
Has acidic properties PROPERTIES
because the covalent bond
between oxygen and hydrogen
is so polar; for example,

Acetic acid, which gives vinegar
its sour taste

Acetic acid Acetate ion

Some biologically important Found in cells in the ionized
form with a charge of 1– and
chemical groups called a carboxylate ion (here,
specifically, the acetate ion).
Fig. 4-10d

Amino

STRUCTURE NAME OF
Amines COMPOUND

EXAMPLE FUNCTIONAL
Acts as a base; can PROPERTIES
pick up an H+ from
the surrounding
solution (water, in
living organisms).
Glycine

Because it also has a
carboxyl group, glycine
is both an amine and
a carboxylic acid; (nonionized) (ionized)
compounds with both
groups are called amino Ionized, with a
acids. charge of 1+, under
cellular conditions.

Some biologically important
chemical groups
 Fig. 4-10e

Sulfhydryl

STRUCTURE NAME OF
Thiols COMPOUND
Some biologically important

(may be
written HS—)
chemical groups

EXAMPLE FUNCTIONAL
Two sulfhydryl groups PROPERTIES
can react, forming a
covalent bond. This
“cross-linking” helps
stabilize protein
structure.

Cysteine Cross-linking of
cysteines in hair
proteins maintains the
Cysteine is an important
sulfur-containing amino curliness or straightness
acid. of hair. Straight hair can
be “permanently” curled
by shaping it around
curlers, then breaking
and re-forming the
cross-linking bonds.
Fig. 4-10f

Phosphate

STRUCTURE NAME OF
Organic phosphates COMPOUND

EXAMPLE FUNCTIONAL
Contributes negative charge PROPERTIES
to the molecule of which it is
a part (2– when at the end of a
molecule; 1– when located
internally in a chain of
Glycerol phosphate phosphates).
Has the potential to react
In addition to taking part in with water, releasing energy.
many important chemical
reactions in cells, glycerol
phosphate provides the
backbone for phospholipids,
the most prevalent molecules in
Some biologically important
cell membranes. chemical groups
ATP: An Important Source of Energy for Cellular
Processes
One phosphate molecule, adenosine
triphosphate (ATP), is the primary energy-
transferring molecule in the cell
ATP consists of an organic molecule called
adenosine attached to a string of three
phosphate groups

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Fig. 4-10g

Methyl

STRUCTURE NAME OF
Methylated compounds COMPOUND

EXAMPLE FUNCTIONAL
Addition of a methyl group PROPERTIES
to DNA, or to molecules
bound to DNA, affects
expression of genes.

Arrangement of methyl
groups in male and female
sex hormones affects
5-Methyl cytidine their shape and function.

5-Methyl cytidine is a
component of DNA that has
been modified by addition of
the methyl group.
Some biologically important
chemical groups
Fig. 4-UN2
The Chemical Elements of Life: A Review

The versatility ‫ براعه‬of carbon makes possible
the great diversity of organic molecules
Variation at the molecular level lies at the
foundation of all biological diversity

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Fig. 4-UN3

Adenosine
Fig. 4-UN4

Reacts
with H2O
P P P Adenosine Pi P P Adenosine Energy
ATP Inorganic ADP
phosphate
Fig. 4-UN5

Reacts
with H2O
P P P Adenosine Pi P P Adenosine Energy
ATP Inorganic ADP
phosphate
Fig. 4-UN6
Fig. 4-UN7

a b c d e
Fig. 4-UN8
Fig. 4-UN9

L-dopa D-dopa
Fig. 4-UN10
Fig. 4-UN11
Fig. 4-UN12
Fig. 4-UN13
You should now be able to:

1. Explain how carbon’s electron configuration
explains its ability to form large, complex,
diverse organic molecules

2. Describe how carbon skeletons may vary and
explain how this variation contributes to the
diversity and complexity of organic molecules

3. Distinguish among the three types of isomers:
structural, geometric, and enantiomer

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4. Name the major functional groups found in
organic molecules; describe the basic
structure of each functional group and outline
the chemical properties of the organic
molecules in which they occur

5. Explain how ATP functions as the primary
energy transfer molecule in living cells

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