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Biochemistry of Cells

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Title: Biochemistry of Cells


1
Biochemistry of Cells
2
Uses of Organic Molecules
  • Americans consume an average of 140 pounds of
    sugar per person per year

Cellulose, found in plant cell walls, is the most
abundant organic compound on Earth
3
Uses of Organic Molecules
  • A typical cell in your body has about 2 meters of
    DNA
  • A typical cow produces over 200 pounds of methane
    gas each year

4
Water
  • About 60-90 percent of an organism is water

Water is used in most reactions in the body
Water is called the universal solvent
5
Water Properties
CAN YOU NAME MORE?
  • Polarity

Cohesiveness
Adhesiveness
Surface Tension
6
Carbon-based Molecules
  • Although a cell is mostly water, the rest of the
    cell consists mostly of carbon-based molecules

Organic chemistry is the study of carbon compounds
7
Carbon is a Versatile Atom
  • It has four electrons in an outer shell that
    holds eight

Carbon can equally share its electrons with other
atoms to form up to four covalent bonds
8
Hydrocarbons
  • The simplest carbon compounds

Contain only carbon hydrogen atoms
9
Carbon can use its bonds to
  • Attach to other carbons

Form an endless diversity of carbon skeletons
10
Large Hydrocarbons
  • Are the main molecules in the gasoline we burn in
    our cars

The hydrocarbons of fat molecules provide energy
for our bodies
11
Shape of Organic Molecules
  • Each type of organic molecule has a unique
    three-dimensional shape

The shape determines its function in an organism
12
Functional Groups are
  • Groups of atoms that give properties to the
    compounds to which they attach

Lost Electrons
Gained Electrons
13
Common Functional Groups
14
Giant Molecules - Polymers
  • Large molecules are called polymers

Polymers are built from smaller molecules called
monomers repeating subunits
Biologists call them macromolecules
15
Examples of Polymers
  • Proteins

Lipids
Carbohydrates
Nucleic Acids
16
Most Macromolecules are Polymers
  • Polymers are made by stringing together many
    smaller molecules called monomers

Nucleic Acid Monomer
Phosphate Group Negative
17
Linking Monomers
Cells link monomers by a process called
dehydration synthesis (removing a molecule of
water)
Remove H
H2O Forms
Remove OH
This process joins two sugar monomers to make a
double sugar
18
Breaking Down Polymers
  • Cells break down macromolecules by a process
    called hydrolysis (adding a molecule of water)

Water added to split a double sugar
19
Macromolecules in Organisms
  • There are four categories of large molecules in
    cells

Carbohydrates
Lipids
Proteins
Nucleic Acids
20
Carbohydrates
  • Carbohydrates include
  • Small sugar molecules in soft drinks
  • Long starch molecules in pasta and potatoes

21
Monosaccharides
  • Called simple sugars

Include glucose, fructose, galactose
Have the same chemical, but different structural
formulas
C6H12O6
22
Monosaccharides
  • Glucose is found in sports drinks

Fructose is found in fruits
Honey contains both glucose fructose
Galactose is called milk sugar
23
Isomers
  • Glucose fructose are isomers because theyre
    structures are different, but their chemical
    formulas are the same

24
Rings
  • In aqueous (watery) solutions, monosaccharides
    form ring structures

25
Cellular Fuel
  • Monosaccharides are the main fuel that cells use
    for cellular work

ATP
26
Disaccharides
  • A disaccharide is a double sugar

Theyre made by joining two monosaccharides
Involves removing a water molecule (dehydration)
27
Disaccharides
  • Common disaccharides include
  • Sucrose (table sugar)
  • Lactose (Milk Sugar)
  • Maltose (Grain sugar)

28
Disaccharides
  • Sucrose is composed of glucose fructose

Maltose is composed of 2 glucose molecules
Lactose is made of galactose glucose
GLUCOSE
29
Polysaccharides
  • Complex carbohydrates

Composed of many sugar monomers linked together
Polymers of monosaccharide chains
30
Examples of Polysaccharides
Glucose Monomer
Starch
Glycogen
Cellulose
31
Starch
  • Starch is an example of a polysaccharide in plants

Plant cells store starch for energy
Potatoes and grains are major sources of starch
in the human diet
32
Glycogen
  • Glycogen is an example of a polysaccharide in
    animals

Animals store excess sugar in the form of glycogen
Glycogen is similar in structure to starch
33
Cellulose
  • Cellulose is the most abundant organic compound
    on Earth

It forms cable-like fibrils in the tough walls
that enclose plants
It is a major component of wood
It is also known as dietary fiber
34
Cellulose
SUGARS
35
Dietary Cellulose
  • Most animals cannot derive nutrition from fiber

They have bacteria in their digestive tracts that
can break down cellulose
36
Sugars in Water
  • Simple sugars and double sugars dissolve readily
    in water

WATER MOLECULE
They are hydrophilic, or water-loving
SUGAR MOLECULE
37
Lipids
  • Lipids are hydrophobic water fearing

Do NOT mix with water
Includes fats, waxes, steroids, oils
FAT MOLECULE
38
Function of Lipids
  • Fats store energy, help to insulate the body, and
    cushion and protect organs

39
Types of Fatty Acids
  • Unsaturated fatty acids have less than the
    maximum number of hydrogens bonded to the carbons
    (a double bond between carbons)

Saturated fatty acids have the maximum number of
hydrogens bonded to the carbons (all single bonds
between carbons)
40
Types of Fatty Acids
Single Bonds in Carbon chain
Double bond in carbon chain
41
Triglyceride
  • Monomer of lipids

Composed of Glycerol 3 fatty acid chains
Glycerol forms the backbone of the fat
Organic Alcohol
42
Triglyceride
Fatty Acid Chains
Glycerol
43
Fats in Organisms
  • Most animal fats have a high proportion of
    saturated fatty acids exist as solids at room
    temperature (butter, margarine, shortening)

44
Fats in Organisms
  • Most plant oils tend to be low in saturated fatty
    acids exist as liquids at room temperature
    (oils)

45
Fats
  • Dietary fat consists largely of the molecule
    triglyceride composed of glycerol and three fatty
    acid chains

Fatty Acid Chain
Glycerol
Dehydration links the fatty acids to Glycerol
46
Phospholipids
  • Contains Phosphate group and two fatty acid tails
  • Primary component of cell membranes.
  • Has both hydrophilic and hydrophobic properties
  • Phosphate head is hydrophilic (polar) PO4-
  • Fatty acid tails are hydrophobic

47
Steroids
  • The carbon skeleton of steroids is bent to form 4
    fused rings

Cholesterol
Cholesterol is the base steroid from which your
body produces other steroids
Estrogen
Testosterone
Estrogen testosterone are also steroids
48
Synthetic Anabolic Steroids
  • They are variants of testosterone

Some athletes use them to build up their muscles
quickly
They can pose serious health risks
49
Proteins
  • Proteins are polymers made of monomers called
    amino acids

All proteins are made of 20 different amino acids
linked in different orders
Proteins are used to build cells, act as hormones
enzymes, and do much of the work in a cell
50
Four Types of Proteins
Storage
Structural
Contractile
Transport
51
20 Amino Acid Monomers
52
Structure of Amino Acids
Amino group
Carboxyl group
  • Amino acids have a central carbon with 4 things
    bonded to it

R group
Amino group -NH3
Carboxyl group -COOH
Hydrogen -H
Side groups
Side group -R
Serine-hydrophillic
Leucine -hydrophobic
53
Linking Amino Acids
Carboxyl
  • Cells link amino acids together to make proteins

Amino
Side Group
The process is called dehydration synthesis
Dehydration Synthesis
Peptide bonds form to hold the amino acids
together
Peptide Bond
54
Primary Protein Structure
The primary structure is the specific sequence of
amino acids in a protein
Amino Acid
55
Protein Structures
  • Secondary protein structures occur when protein
    chains coil or fold due to hydrogen bonding
    between the carboxyl and amino groups.

When the R groups interact with each other join
together, the tertiary structure forms also
known as protein folding.
Quartinary structure is when two or more tertiary
polypeptide units come together to form a
functional protein.
56
Protein Structures
Hydrogen bond
Pleated sheet
Polypeptide (single subunit)
Amino acid
(a) Primary structure
Hydrogen bond
Alpha helix
(c) Tertiary structure
(b) Secondary structure
(d) Quaternary structure
57
Denaturating Proteins
Changes in temperature pH can denature (unfold)
a protein so it no longer works
Cooking denatures protein in eggs
Milk protein separates into curds whey when it
denatures
58
Changing Amino Acid Sequence
Substitution of one amino acid for another in
hemoglobin causes sickle-cell disease
7. . . 146
2
3
6
1
4
5
(a) Normal red blood cell
Normal hemoglobin
7. . . 146
2
3
1
6
4
5
(b) Sickled red blood cell
Sickle-cell hemoglobin
59
Nucleic Acids
  • Store hereditary information

Contain information for making all the bodys
proteins
Two types exist --- DNA RNA
60
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61
Nucleic Acids
Nitrogenous base (A,G,C, or T)
Nucleic acids are polymers of nucleotides
Phosphate group
Thymine (T)
Sugar (deoxyribose)
Phosphate
Base
Sugar
Nucleotide
62
Bases
  • Each DNA nucleotide has one of the following
    bases

Thymine (T)
Cytosine (C)
  • Adenine (A)
  • Guanine (G)
  • Thymine (T)
  • Cytosine (C)

Adenine (A)
Guanine (G)
63
Nucleotide Monomers
Backbone
  • Form long chains called DNA

Nucleotide
Nucleotides are joined by sugars phosphates on
the side
Bases
DNA strand
64
DNA
  • Two strands of DNA join together to form a double
    helix

Base pair
Double helix
65
RNA Ribonucleic Acid
Nitrogenous base (A,G,C, or U)
  • Ribose sugar has an extra OH or hydroxyl group

Uracil
Phosphate group
It has the base uracil (U) instead of thymine (T)
Sugar (ribose)
66
Summary of Key Concepts
67
Nucleic Acids
68
Macromolecules
69
Macromolecules
70
End
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