lecture 4 organic molecules and inorganic molecules 1. inorganic molecules. 2. water 3. organic...
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Lecture 4 Organic
molecules and Inorganic molecules
1. Inorganic molecules.2. Water3. Organic molecules
Prepared by Mayssa Ghannoum
Overview
In this lecture we will examine the major group of molecules that make up living organisms along with some of the properties and functions of these molecules.
Living organisms are composed of both inorganic and organic molecules.
Inorganic molecules
Inorganic molecules: are relatively small, simple molecules that
do not contain carbon atom C. There are a few carbon-containing
molecules, such as carbon monoxide and carbon dioxide, that are
also classified as inorganic molecules. Inorganic compounds,
such as water, are made up of inorganic molecules
Minerals are mainly oxides and sulfides, which are strictly
inorganic. In fact, most of the earth and the universe is inorganic
Water molecule
Water is the only common substance to exist
in the natural environment in all three physical
states of matter: solid, liquid, and gas.
All living organisms require water more than
any other substance
The polarity of water molecules results in hydrogen bonding
Water is a small polar molecule made of
one oxygen atom joined to 2 hydrogen
atoms.
The oxygen atom has slight negative charge
and the 2 hydrogen atoms have slight
positive charges.
Polarity allows water molecules to form
hydrogen bonds with each other
Properties of water
CohesionAdhesionHigh Specific HeatHigh Heat of VaporizationLess Dense as a SolidSolvent of Life
Cohesion
Attraction between particles of the same substance ( this is why water is attracted to itself).
Results in Surface tension (a measure of the strength of water’s surface).
Produces a surface film on water that allows insects to walk on the surface of water.
Cohesion due to hydrogen bonding contributes to the transport of water and dissolved nutrients against gravity in plants.
Adhesion
Is an Attraction between different substances, for example, between water and plant cell walls.
Adhesion also causes water to:
Form spheres & hold onto
plant leaves
Attach to a silken spider
web
High Specific Heat
Water is effective as a heat bank because it can absorb or release a relatively large amount of heat with only a slight change in its own temperature.
Heat and temperature
Kinetic energy: is the energy of motion.
Heat: is a form of energy
Temperature measures the intensity of heat due to the average kinetic energy of molecules.
Celsius Scale is used as temperature indicator .
The unit of heat is calorie (cal).
High Specific Heat
The specific heat is the amount of heat that must be
absorbed or lost for one gram of the substance to change its
temperature by one Celsius.
The specific heat of water is 1 cal/g/ºC
Water resists changing its temperature because of its high
specific heat which can be traced to: hydrogen bonding
Heat is absorbed when hydrogen bonds break. Heat is released when hydrogen bonds form.
High Heat of Vaporization
Evaporation: is transformation of a substance from liquid to gas.
Heat of vaporization is the heat a liquid must absorb for 1 g to be converted to gas.
As a liquid evaporates, its remaining surface cools, a process called evaporative cooling.
Evaporative cooling of water helps stabilize temperatures in organisms and bodies of water.
Water is less Dense as a Solid
Ice is less dense as a solid
than as a liquid (ice floats)
Liquid water has hydrogen
bonds that are constantly
being broken and
reformed.
Frozen water forms a
crystal-like lattice whereby
molecules are set at fixed
distances.
Acids, Bases and PH
A water molecule can transfer an H+ to another water molecule to form H3O+ (Hydronium ion ) and OH– (Hydroxide).
Hydrogen Ions Hydroxide ions Acid Base
The pH of a solution is defined by the negative
logarithm of H+ concentration, written as pH = –
log [H+]
H2O H+ + OH-
The PH Scale Biologists use something called the pH scale.
Most Biological fluids pH value is within the range 6-8.
Adding certain solutes, called acids and bases, modifies the concentrations of H+ and OH–.(Fig3.9).
An acid is any substance that increases the [H+] .
Acidic solutions have pH values less than 7.
A base is any substance that reduces the [H+].
Basic solutions have pH values greater than 7.
The PH Scale
Buffers
Weak acids or bases that react with strong acids or bases to prevent sharp, sudden changes in pH (neutralization).
Produced naturally by the body to maintain homeostasis
Weak Acid Weak Base
Organic molecules
Are molecules that contain two or more carbon atoms.
All living things are made up of four classes of large biological
molecules:
1. Carbohydrates 2. Lipids 3. Proteins 4. Nucleic acids
Macromolecules are polymers, built from monomers
A polymer (poly- means many) :is a long molecule consisting of
many similar or identical building blocks linked by covalent bonds.
A monomer (mono- means one): is the repeating unit that serves as
the building block of a polymer.
Carbohydrates serve as fuel and building material
Carbohydrates include both sugars and polymers of sugars
1) Sugars
a- Monosaccharide ≡ single sugar e.g., glucose (The major nutrient in the cell) and fructose
b- Disaccharide ≡ consists of two monosaccharides joined by a glycosidic linkage e.g Maltose also called malt sugar (glucose +glucose)
Sucrose also called table sugar (glucose + fructose)
Carbohydrates serve as fuel and building material
2) Polysaccharides
a) Storage polysaccharide e.g., starch (represents stored energy)
b) Structural polysaccharide e.g. cellulose ( is a major component of the tough walls that enclose plant cells).
Glycosidic linkage is a covalent bond formed between two monosaccharides.
Lipids are a diverse group of hydrophobic molecules
Lipids are grouped together because they share one
important trait: They mix poorly, if at all, with water.
Composition of Lipids:
C, H, and small amounts of O.
Types of lipids:
1) Fats: are constructed from 2 kinds of smaller
molecules glycerol and fatty acids. Fats have 3 fatty
acids attached to a glycerol.
There are 2 types of fats:
1- Saturated fat: a molecule without any
double bonds between carbon atoms
composing the chain (e.g., butter).
2- Unsaturated fat: a molecule that has
one or more double bonds, formed by the
removal of hydrogen atoms from the
carbon skeleton (e.g., fats of plants and
fishes).
2) Phospholipids
Phospholipids have 2 fatty acids and a phosphate
group attached to glycerol
Phospholipids are essential for cells because they
make up cell membranes.
The two ends of phospholipids show different
behavior toward water.
a- Hydrocarbon tails are hydrophobic and are
excluded from water.
b- The hydrophilic head that has an affinity for water
3) Steroids
Many hormones, as well as cholesterol, are steroids
Cholesterol is a common component of animal cell
membranes and is also the precursor from which other
steroids are synthesized.
Cholesterol is synthesized in the liver
A high level of cholesterol in the blood may contribute to
atherosclerosis (Hardening of the arteries)
Proteins Proteins are built from 20 kinds of amino acids.
Amino acids: are organic molecules possessing both carboxyl and
amino groups.
Examples of amino acids: serine, threonine, lysine, tryptophan,
proline…etc
Polypeptides: are polymers of amino acids linked by peptide bonds.
- A protein is consists of 1 or more polypeptides.
- At one end of the polypeptide chain is a free amino group
(N-terminus);
at the opposite end is free carboxyl group (C-terminus).
Proteins have important and Various functions
1. Enzymes: Catalysis of cellular reactions
2. Structural Proteins: Maintain cell shape
3. Transport: Transport in cells/bodies (e.g. hemoglobin).
Channels and carriers across cell membrane.
4. Communication: Chemical messengers, hormones, and
receptors.
5. Defensive: Antibodies and other molecules that bind to foreign
molecules and help destroy them.
6. Contractile: Muscular movement.
7. Storage: Store amino acids for later use (e.g. egg white).
Levels of Proteins structure
1. Primary structure: is a unique sequence of amino acid.
2. Secondary structure: is a coiled and folded chain with repeated segments polypeptide.
3. Tertiary structure: is a superimposed on the patterns of secondary structure.
4. Quaternary structure: is a protein that consists of two or more polypeptide chains. e.g. hemoglobin.
Nucleic Acids store and transmit hereditary information for all living things
There are two types of nucleic acids in living things:
A. Deoxyribonucleic Acid (DNA)
Contains genetic information of all living organisms. Has segments called genes which provide information to make each
and every protein in a cell Double-stranded molecule which replicates each time a cell divides.
B. Ribonucleic Acid (RNA)
Three main types called mRNA, tRNA, rRNA RNA molecules are copied from DNA and used to make gene
products (proteins). Usually exists in single-stranded form.
DNA and RNA are polymers of nucleotides that determine the primary structure of proteins
Nucleotide: Subunits of DNA or RNA.
Nucleotides have three components:
1. Pentose sugar (ribose or deoxyribose)
2. Phosphate group to link nucleotides (-PO4)
3. Nitrogenous base (A,G,C,T or U)
Purines: Have 2 rings.
Adenine (A) and guanine (G)
Pyrimidines: Have one ring.
Cytosine (C), thymine (T) in DNA or uracil (U) in RNA.
James Watson and Francis Crick Determined the 3-D Shape of DNA in 1953
Double helix: The DNA molecule is a double helix.Antiparallel: The two DNA strands run in opposite
directions.
Strand 1: 5’ to 3’ direction (------------>)
Strand 2: 3’ to 5’ direction (<------------)Complementary Base Pairing: A & T (U) and G & C.
A on one strand hydrogen bonds to T (or U in RNA).
G on one strand hydrogen bonds to C.
Replication: The double-stranded DNA molecule can easily replicate based on A=T and G=C pairing.
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