Chapter 3 - Lecture Notes - PDF

Summary

This document is lecture notes on chapter 3 of a biology course that covers organic molecules, such as carbohydrates, proteins and nucleic acids. The chapter details the chemical properties of carbon and its role in organic molecules, including examples and concepts like monomers, polymers, and functional groups.

Full Transcript

Chapter 3

The Chemical Basis of
Life II: Organic
Molecules
 Group Work
Which of these is a pure hydrocarbon and what features of the molecule are you examining
to make your choice?

Which molecule(s) are fully nonpolar molecule and which one(s) is/are “amphipathic?”
3.1 The Carbon Atom and Carbon-Containing Molecules

Section 3.1 Learning
Outcomes
1. Explain the properties of
carbon that make it the
chemical basis of all life
2. Describe the variety and
Loading… chemical characteristics of
common functional groups
of organic compounds
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Is an Essential Element for Life

Organic molecules contain carbon
-
-
Carbon has 4 electrons in its outer
valence shell
It needs 4 more electrons to fill - -
the valence shell
Can form up to four covalent -
bonds
This is the max # of bonds any
-
atom can make
Carbon
Carbon is a “scaffold” atom, aka Atom
the backbone or chain of a lot of
biological molecules
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Is an Essential Element for Life
Carbon can form polar or nonpolar covalent bonds, depending on the
electronegativity of the bonding partner
Pure Hydrocarbons are nonpolar molecules containing a carbon backbone
Have only C-C and C-H bonds Examples of molecules
Hydrophobic and poorly soluble in water that are pure
HYDROCARBONs.
Notice the symmetry

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of these molecules.
They do not have
polar regions that
are positive or
negative.
These repel water,
but aggregate
together (like oil in
water)
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Is an Essential Element for Life
Oxygen and nitrogen form polar bonds with carbon
Partial Hydrocarbons have a carbon backbone, but are hydrophilic
and soluble in water
But many molecules in
Biological organisms
δ- are Partial
Hydrocarbon Polar Hydrocarbons.
“chain” “functional Notice the
δ- δ+group” asymmetry of this
molecule.
IT DOES have polar
regions that are
positive or negative.
These attract water
through attraction of
pos/neg charges.
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Atoms May Be Arranged into Functional Groups
A functional group is a small group of atoms with specific chemical properties & consistent
behavior in chemical reactions.
Why do we care about them? Because they can completely change the function and solubility of the
hydrophobic molecule to which they are attached.

Functional group

Ethane
Ethane yields 20,630 BTUs
Ethanol only yields 11,587 BTUs per
per pound when combusted in
pound when combusted
an engine.
Ethanol will dissolve in water.
Ethane does not dissolve
in water.
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Atoms May Be Arranged into Functional Groups
A functional group exhibits similar chemical properties in all molecules in which
it occurs
3.1 The Carbon Atom and Carbon-Containing Molecules
Carbon Atoms May Be Arranged into Functional Groups
A functional group exhibits similar chemical properties in all molecules in which
it occurs
3.2 Synthesis and Breakdown of Organic Molecules

Section 3.2 Learning
Outcomes
1. Diagram how small
organic molecules are
assembled into larger ones
by dehydration reactions
and how hydrolysis
reactions can reverse this
process
 3.2 Synthesis and Breakdown of Organic Molecules
Imagine you are popping these beads together.
Each bead is a monomer.
The chain you make is called polymer.
Polymers are formed by dehydration reactions
A molecule of water is removed each time a new monomer is added; the process
repeats to form long polymers
Dehydration reactions are catalyzed by enzymes

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3.2 Synthesis and Breakdown of Organic Molecules

When you pull the beads apart it is called a hydrolysis reaction.
A molecule of water is added back each time a monomer is released; the
process repeats to break down a long polymer
Hydrolysis reactions are catalyzed by enzymes

The Molecules of life are polymers!
 Let’s practice

Formation of polymers from monomers typically involves
) removal of a molecule of water
) addition of a molecule of water
) a hydrolysis reaction
) a dehydration reaction
)· both a and d
3.4 Carbohydrates

Section 3.4 Learning
Outcomes
1. Distinguish among
different types of
carbohydrate molecules,
including monosaccharides,
disaccharides, and
polysaccharides
2. Relate the functions of
plant and animal
polysaccharides to their
structure
3.3 Overview of the 4 Major Classes of Organic Molecules
The 4 major classes of organic molecules are carbohydrates, lipids,
proteins, and nucleic acids
What structures are you familiar with that are composed of carbohydrates?
3.4 Carbohydrates

Carbohydrates
Monomer = monosaccharide
Ring backbone containing carbons AND one oxygen atom
Ring can be a pentose (5 sides) or hexose (6 sides)

Bio 190 students needs to recognize and
identify the molecular structure of a
monosaccharide sugar when they see it
3.4 Carbohydrates
Monosaccharides and Disaccharides Are Simple
Carbohydrates
dehydration reaction to form
Monosaccharides can be joined together by a ______________
disaccharides
Sucrose (table sugar) is a familiar disaccharide that is formed from glucose +
fructose
Lactose and maltose are also disaccharides

The covalent bond formed between
2 sugars is called a glycosidic bond
Disaccharides can be broken down
through ____________
hydrolysis reactions
Monosaccharides and disaccharides
often function as an energy source
3.4 Carbohydrates
Polysaccharides Are Carbohydrate Polymers
Polysaccharides are formed when many monosaccharides are linked together;
examples of polysaccharides include
starch energy storage in plant cells
glycogen energy storage in certain animal cells
cellulose provides strength to plant cell walls
peptidoglycans found in cell walls of certain bacteria
chitin found in cell walls of fungi; found in exoskeletons of arthropods
glycosaminoglycans found in connective tissues surrounding animal cells
(ex: abundant in cartilage)

· need to know !
3.7 Nucleic Acids

Section 3.7 Learning
Outcomes
1. Describe the 3
components of a nucleotide
2. Distinguish between the
structures of DNA and RNA
3. Explain how certain bases
pair with others in DNA
3.7 Nucleic Acids
Nucleotides Are the Building Blocks of DNA and RNA
Nucleic acids are POLYMERS that are responsible for the storage,
expression, and transmission of genetic information

Two classes:
Deoxyribonucleic acid (DNA)
Stores genetic information encoded in the sequence of
nucleotide monomers
Ribonucleic acid (RNA)
Decodes DNA into instructions for linking together a specific
sequence of amino acids to form a polypeptide chain
3.7 Nucleic Acids
Nucleotides Are the Building Blocks of DNA and RNA
Nucleotides are the monomer building blocks of nucleic acids
Nucleotides are composed of three
components:
a phosphate group

I a pentose sugar (ribose or
deoxyribose)
a nitrogenous base H50H
-
T

* de =
removal of

oxygen !
Bio 190 students need to recognize the
difference in the ribose sugar that
differentiates a deoxyribonucleotide from
a ribonucleotide.

OHc.
OH -
Fig 3.21, Biology,
 Brooker

3.7 Nucleic Acids
Nucleotides Are the Building Blocks of DNA and RNA

The nitrogenous bases in
nucleotides: < 2 rings
The purines, adenine (A)
and guanine (G), have a

!
double-ring structure Iring
-
The pyrimidines, cytosine
(C) and thymine (T), have
a single-ring structure
remember : Dure As Gold

"Cut pie"
Py = pie tosine
cut
=
Gracil
thymine
3.7 Nucleic Acids
DNA Is Composed of Two Strands That Form a
Double Helix
A DNA molecule consists
of 2 strands of nucleotides,
coiled around each other to
form a double helix
The strands are held
together by hydrogen
bonds that form between
complementary “base
pairs”
A pairs with T
C pairs with G

↑
DNAbase
3.7 Nucleic Acids
RNA Is Usually Single Stranded
Although they are generally similar,
the structure of RNA differs in a few
ways from the structure of DNA
RNA is usually single stranded
RNA nucleotides contain the sugar
ribose
RNA uses the nitrogenous base
uracil in place of thymine
--

DNA !
RNA !
3.6 Proteins

Section 3.6 Learning
Outcomes
1. Give examples of the
general functions that are
carried out by different
proteins
2. Describe how amino acids
are joined to form a
polypeptide
3. Diagram and explain the 4
levels of protein structure
4. Outline the factors that
determine protein shape and
function
5. Define protein domain
3.6 Proteins

Proteins perform a variety of diverse functions in cells
The MOST diverse molecule type
3.6 Proteins
Amino Acids Are the Building Blocks of Proteins
Proteins are polymers composed of 20 different amino acids

- -

www.bareblends.com
 3.6 Proteins
Amino Acids Are the Monomer of Proteins
Each amino acid has a common core structure (list below) as well as
a variable side chain (designated R)
α-carbon

I amino group
carboxylic acid group
hydrogen
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Carboxylic Acid
functional group
Muddy area in 190: Students have difficulties identifying the
biological monomers.

Examine the molecules here. They clearly are different, but you need
some rules to describe those differences.
Rules:
A monosaccharide (sugar) contains a ring structure that includes
carbons and ONE oxygen
Nucleotides have 3 parts: phosphate group, sugar, base
Amino acids do not have a ring and are named based on
functional groups that they contain amino group, acid group
"fist
"

"butterfly" "hang10"
Discuss in your group WHY these rules work to “memorize” the
monomer structures. If they don’t work for you, makeO'
up your own
rules.

amiro acid nucleotide monosaccharise
 3.6 Proteins
Amino Acids Are the Building Blocks of Proteins
The 20 amino acids are categorized by the chemical properties of
the side chains; some R groups are polar while others are nonpolar
!
Nonpolar (hydrophobic) amino acids: non-polar
so
↑ no oxygen RECALL Activity: What
-
-
+ features make molecules non-
+ polar?

Side chain = R-group = residue
3.6 Proteins
Amino Acids Are the Building Blocks of Proteins
Polar (hydrophilic) amino acids: RECALL Activity: What features
oxygen make molecules polar?
↓
A
polar be -
3.6 Proteins
Proteins Have a Hierarchy of Structure or “Folding”
Proteins structure is characterized at 4 progressive levels:
Primary structure is the linear sequence of amino acids (encoded by genes);
-

peptide bonds contribute to primary structure
-

Secondary structure forms as some chemical groups (NH and CO) of the
-

backbone interact with each other via hydrogen bonds & interact +g

α helices and β pleated sheets are common; turns and loops can also form as
- -

part of secondary structure
Tertiary structure is the overall 3-dimensional folded shape of the protein; R
-

groups participate in chemical interactions and all types of bonds can potentially
contribute to tertiary structure
For some proteins, this is the final level of structure
Quaternary structure occurs when -
2 or more protein subunits are assembled
-

together to form a functional complex; all types of chemical bonds can potentially
contribute to quaternary structure
-
3.6 Proteins
Proteins Have a Hierarchy of Structure or “Folding”

Quaternary Structure (2 or more proteins come together)

Tertiary Structure (3-dimensional shape )

Secondary Structure (α helices & β pleated sheets )

Primary Structure (amino
acids)
3.6 Proteins
Proteins Have a Hierarchy of Structure or “Folding”
Protein 3D Structure Is Determined by Several Factors
More Acidic More Basic
solution solution
1 7 H+ H+ 14
H+
H+ H+ H+
H+ H+
H+
H+ H+ H+
H+
H+ H+
H+ H+
H+
H+ H+ H+
H+ H+
H+ H+
H+ H+
H+
H+ H+
H+

H+ H+ The 1’ structure has
H+ H+
not changed, but the
H+
H+
H+
H+ H+
pH of the solution
H+ H+
changed, and hence
H+
H+ the 3’ structure
H+
H+ H
H++
H+ changed.
H+
Food Hmash
+ travels
H+ H+ from stomachH+(ph2)
H+H+
H+ into intestine (pH
H+ H+
H+ 8)
H+
H+
H+

H+
3.5 Lipids Section 3.5 Learning
Outcomes
1. List the different classes
of lipid molecules important
in living organisms
2. Diagram the structure of a
triglyceride, and explain
how it is formed and how
its structure is affected by
the presence of saturated
and unsaturated fatty acids
3. Explain why some fats are
solid at room temperature
and others are liquid
4. Discuss how triglycerides
function as energy-storage
molecules
5. Explain why
3.5 Lipids
Lipids are composed predominantly of hydrogen and carbon atoms
They do not have a monomer unit.
A defining feature of lipids is that they are nonpolar and therefore very insoluble
in water
Lipids can be described as hydrophobic hydrocarbons
Lipids are structurally diverse

Carboxylic acid functional
Fat or hydrocarbon part group
3.5 Lipids
The Fatty Acid
-long, linear carbon chain or backbone
-carboxylic acid group at one end

↓ 3 representations of same lipid called a “fatty acid”
Carboxylic acid functional
Fat or hydrocarbon part group

1.

2.

3.
Muddy area in 190: Students have difficulties identifying the
biological monomers.

Examine the molecules here. They clearly are different, but you need
some rules to describe those differences.
Rules:
A sugar contains a ring structure that contains carbons and ONE
oxygen
Nucleotides contain 3 parts: phosphate group, sugar, base
Amino acids do not have a ring and are named based on
functional groups that they contain amino group, acid group
Lipids have long (linear or ring) carbon backbones.
3.5 Lipids

Type #1: Triglycerides are the molecules commonly known as fats and oils

This is a stick
structure drawing of
a triglyceride.
3.5 Lipids

Saturated fatty acids v Unsaturated fatty acids

Carbons in the chain
“saturated” with what? With
H3 4 H
Hydrogen atoms
1 2

Monounsaturated fatty
acids contain one C=C,
which introduces a kink
into the shape
Polyunsaturated fatty
acids contain two or more
C=C
3.5 Lipids

Due to their straight structure, saturated fatty acids can pack together more
tightly than unsaturated fatty acids
Typical of animal fats that Typical of plant fats that are
are solid at room temp liquid at room temp

Considered “healthier” fats. For one
reason is there is less fat contained per
unit volume (aka, less calories per bite)
3.5 Lipids
Type #2: Phospholipids compose the semi-permeable
membrane surrounding ALL cells

NEW term! The fatty tails attract each other side-by-
side through “Hydrophobic interactions”
3.5 Lipids
Type #3: Steroids contain Rings of carbon atoms
Steroids have four interconnected rings of carbon atoms
They are primarily composed of carbon and hydrogen and are usually insoluble in
water

© 2015 Pearson Education, Inc.
3.5 Lipids
Type #4: Waxes Are Complex Lipids That Prevent Water
Loss from
Organisms
Waxes are very, very long fatty acids
Very nonpolar, thus they exclude water
Waxes are used to protect organisms from water loss or as structural
elements
Ex: Waxy surface on leaves
Ex: Beeswax in honeycombs