WEEK 2d Biological Molecules ppt.pptx

Transcript

BIOLOGICAL
MOLECULES
Biological Molecules
Biologicalmolecules are often
referred to as the molecules of
life (bio-molecules) that are
basically found in a living cell
and categorized as organic and
inorganic molecules in general.
Organic biomolecules
The organic biomolecules are proteins,
carbohydrates, lipids and nucleic
acids.
Without any of these four molecules,
a cell and organism would not be able
to live.
Important either structurally or
functionally for cells.
Inorganic molecules
Most known inorganic molecules are
water and minerals, which are still
important for the normal functioning
of the cell.
Carbohydrates
A carbohydrate molecule is made of
atoms of carbon, hydrogen and oxygen.
They are an important source of energy.
They also provide structural support for
cells and help with communication
between cells (cell-cell recognition).
They are found in the form of either a
sugar or many sugars linked together,
called saccharides.
Carbohydrates
Based on the number sugar units they contain; they
are categorized into three;
A single sugar molecule containing carbohydrate is
known as a monosaccharides, while two and many
having are regarded as disaccharides and
polysaccharides.
Each of the sugar molecules are bonded together
through the glycosidic linkage/s.
Carbohydrates
are polyhydroxy aldehydes or ketones,
or substances that yield these compounds on
hydrolysis.
Example: Glucose is aldehyde and fructose is Ketone.
Carbohydrates
Monosaccharides - simple sugars with multiple
OH groups.
Based on number of carbons (3, 4, 5, 6), a
monosaccharide is a triose, tetrose, pentose or
hexose.
Disaccharides - 2 monosaccharides covalently
linked
Oligosaccharides - a few monosaccharides
covalently linked.
Polysaccharides - polymers consisting of chains
of monosaccharide or disaccharide
Monosaccharides
Monosaccharides containing the
aldehyde group are classified as
aldoses, and those with a ketone group
are classified as ketoses.
Aldoses are reducing sugars; ketoses
are non-reducing sugars..
Glucose
Glucoseis the most important carbohydrate fuel
in human cells.
Its concentration in the blood is about 1 gdm-3
(1 gram per cubic decimeter)
Energy is released when the molecules are
metabolized.
Two glucose molecules react to form the
disaccharide maltose.
Starch and cellulose are polysaccharides made
up of glucose units.
Galactose

Galactose reacts with glucose to make
the disaccharide lactose.
Galactose cannot play the same part in
respiration as glucose.
Fructose
Fructose, glucose and galactose are all
hexoses.
Glucose and galactose are aldoses
(reducing sugars), fructose is a ketose
(a non-reducing sugar).
Fructose reacts with glucose to make
the disaccharide sucrose.
Ribose and deoxyribose
Ribose and deoxyribose are
pentoses.
The ribose unit forms part of a
nucleotide of RNA.
The deoxyribose unit forms part of
the nucleotide of DNA
Disaccharides
Monosaccharides are rare in nature.
Most sugars found in nature are disaccharides.
These form when two monosaccharides react.
Disaccharides are soluble in water, but they are
too big to pass through the cell membrane by
diffusion.
They are broken down in the small intestine during
digestion to give the smaller monosaccharides
that pass into the blood and through cell
membranes into cells.
Hydrolysis reaction
Hydrolysis reaction and is the
reverse of a condensation reaction
and it releases energy.
Condensation reaction
Condensation reaction takes place by releasing
water. This process requires energy.
A glycosidic bond forms and holds the two
monosaccharide units together.
The three most important disaccharides are
sucrose, lactose and maltose.
They are formed from the forms of the
appropriate monosaccharides.
Sucrose is a non-reducing sugar. Lactose and
maltose are reducing sugars.
 Monosaccharides are used very quickly by cells.
Cellmay not need all the energy immediately and
it may need to store it.
Monosaccharides are converted into disaccharides
in the cell by condensation reactions.
Condensation reactions result in the formation of
polysaccharides.
These are giant molecules which, importantly, are
too big to escape from the cell. These are broken
down by hydrolysis into monosaccharides when
energy is needed by the cell.
Polysaccharides
Monosaccharides can undergo a series
of condensation reactions, adding one
unit after another to the chain until
very large molecules (polysaccharides)
are formed.
This is called condensation
polymerization, and the building blocks
are called monomers.
Starch
Starch is often produced in plants as a way of
storing energy.
It exists in two forms: amylose and
amylopectin.
Amylose is an unbranched polymer of α-
glucose. The molecules coil into a helical
structure. It forms a colloidal suspension in hot
water.
Amylopectin is a branched polymer of α-
glucose. It is completely insoluble in water.
Glycogen
Glycogen is amylopectin with very short
distances between the branching side-chains.
Starch
from plants is hydrolyzed in the body to
produce glucose.
Glucose passes into the cell and is used in
metabolism.
Inside
the cell, glucose can be polymerized to
make glycogen which acts as a carbohydrate
energy store.
 Cellulose

Cellulose is a third polymer made from glucose.
Cellulose serves a very different purpose in nature to
starch and glycogen.
It makes up the cell walls in plant cells. These are
much tougher than cell membranes. This toughness is
due to the arrangement of glucose units in the
polymer chain and the hydrogen-bonding between
neighboring chains.
Cellulose is not hydrolyzed easily and, therefore,
cannot be digested so it is not a source of energy for
humans.
The stomachs of Herbivores contain a specific enzyme
called cellulase which enables them to digest
cellulose.
Summary of carbohydrates
The most abundant organic molecules in
nature
Are polyhydroxy aldehydes or ketones, or
substances that yield these compounds
on hydrolysis
Provide a significant fraction of the
energy in the diet of most organisms
Important source of energy for cells
Can act as a storage form of energy
Summary of carbohydrates
Can be structural components of many
organisms
Can be cell-membrane components
mediating intercellular communication
Can be cell-surface antigens
Can be part of the body’s extracellular
ground substance
Can be associated with proteins and lipid
Part of RNA, DNA, and several coenzymes
 Lipids

Lipidsare a highly variable group of molecules
that include fats, oils, waxes and some steroids.
They are esters of fatty acids and alcohol
(glycerol or chains of alcohols).
Fatty acids are made mostly from chains of
carbon and hydrogen, and they bond to a range
of other types of atoms to form many different
lipids.
The primary function of lipids is to store energy.
Lipids
A lipid called a triglyceride is a fat if it
is solid at room temperature and an oil
if it is liquid at room temperature.
In addition, triglycerides are stored in
the fat cells , also called adipocytes or
lipocytes, and are responsible in
storing fats and lipids which will
facilitate energy store in animal’s
body.
Lipids
Fat cells are categorized in white fat
cells and brown fat cells.
The different is made from their ways
of storing lipids.
White fat cells store one large lipid
drop while brown fat cells store
smaller and multiple droplets of lipids
spreading in the whole body of the
cell.
Lipids
Various types of lipids occur in the human body,
namely:
1) triacylglycerol
2) cholesterol
3) polar lipids, which include phospholipids,
glycolipids and sphingolipids.
Plantleaves are coated with lipids called waxes to
prevent water loss, and the honeycomb in a beehive
is made of beeswax.
Lipids
The basic structure of a lipid includes fatty acid tails.
Each tail is a chain of carbon atoms bonded to hydrogen
and other carbon atoms by single or double bonds.
Lipids that have tail chains with only single bonds
between the carbon atoms are called saturated fats
because no more hydrogens can bond to the tail.
Lipids that have at least one double bond between
carbon atoms in the tail chain can accommodate at
least one more hydrogen and are called unsaturated
fats.
Fats with more than one double bond in the tail are
called polyunsaturated fats.
What are Lipids?
Properties of lipids
Insoluble in water
Longer chains
 More hydrophobic, less soluble
Double bonds increase solubility
Melting points:
Depend on chain length and saturation
Double bonds lead acyl chain disorder and low
melting temperatures
Unsaturated fatty acids are solid at room
temperature.
Importance of lipids
As the main component of cell
membranes (phospholipids)
Insulation of heat and water,
Storing energy, protection and
cellular communication.
Proteins
A protein is a compound made of small carbon
compounds called amino acids.
Amino acids are small compounds that are made of
carbon, nitrogen, oxygen, hydrogen, and sometimes
sulfur.
There are 20 different variable groups, and proteins
are made of different combinations of all 20 different
amino acids.
Several covalent bonds called peptide bonds join
amino acids together to form proteins.
Protein Structure
Primary Structure: It is a specific sequence of amino acids.
The order of amino acids bonded together is detected by
information stored in genes.
Secondary Structure: It is a three-dimensional form of a local
segment of proteins. They are formed by hydrogen bonds
between the atoms along the backbone of the polypeptide
chain.
Tertiary Structure: It is determined by R-groups. It is a three-
dimensional shape of a protein. Many numbers of tertiary
structure fold to form Quaternary Structure.
Quaternary Structure: It is the arrangement of multiple folded
protein subunits in a multi-subunit complex.
Types of Proteins and Their
Functions
 Proteins

Proteins
make up about 15 percent of our total body
mass and are involved in nearly every function of
our body.
For
example, your muscles, skin, and hair all are
made of proteins.
The cells contain about 10,000 different proteins
that provide structural support, transport
substances inside the cell and between cells,
communicate signals within the cell and between
cells, speed up chemical reactions, and control cell
growth.
Nucleic acids
Nucleic acids are complex macromolecules
that store and transmit genetic information.
Nucleic acids are made of smaller repeating
subunits called nucleotides.
Nucleotides are composed of carbon,
nitrogen, oxygen, phosphorus, and
hydrogen atoms.
There are six major nucleotides, all of which
have three units a phosphate, a nitrogenous
base, and a ribose sugar.
When a phosphate group is added to a nucleoside (one sugar molecule plus
one nitrogenous base), it forms a nucleotide.
Sugar molecule

The sugar molecule in nucleotides could be either ribose (C 5H10O5) or deoxyribose
(C5H10O4) and both the sugars are in their Pentagon or furanose state.
Nucleic acids
There are two types of nucleic acids in living
organisms: deoxyribonucleic acid (DNA) and
ribonucleic acid (RNA).
In nucleic acids such as DNA and RNA, the sugar of one
nucleotide bonds to the phosphate of another
nucleotide.
There are five different bases found in nucleotide
subunits that make up DNA and RNA, Adenine,
Cytosine, Guanine, Thymine and Uracil.
Each of these nitrogenous base that sticks out from the
chain is available for hydrogen bonding with other
bases in other nucleic acids.
Nucleic acid
A nucleotide with three phosphate
groups is adenosine triphosphate
(ATP).
ATP is a storehouse of chemical
energy that can be used by cells in a
variety of reactions. It releases
energy when the bond between the
second and third phosphate group is
broken.
 Vitamins
Vitamins are organic compounds that are
needed in small amounts for metabolic
activities.
Many vitamins help enzymes function
well.
Vitamin D is made by cells in your skin.
Some B vitamins and vitamin K are
produced by bacteria living in the large
intestine.
 Vitamins
Sufficient quantities of most vitamins cannot
be made by the body, but a well-balanced
diet can provide the vitamins that are needed.
Some vitamins that are fat-soluble can be
stored in small quantities in the liver and fatty
tissues of the body. Other vitamins are water-
soluble and cannot be stored in the body.
Foods providing an adequate level of these
vitamins should be included in a person’s diet
on a regular basis.
 Water
Water molecules are formed by
covalent bonds that link two hydrogen
(H) atoms to one oxygen (O) atom, and
each water molecule has the same
structure.
It is one of the most plentiful and
essential of compounds, which is a
tasteless and odorless, existing in
gaseous, liquid, and solid states.
 Water
Ithas the important ability to dissolve and as
a media for transportation of many other
substances. The versatility of water as a
solvent is essential to living organisms, as
well.
Water molecules have an unequal distribution
of charges and are called polar molecules,
meaning that they have oppositely charged
regions.
 Minerals
Minerals are inorganic compounds used
by the body as building material, and
they are involved with metabolic
functions.
For example, the mineral iron is needed
to make hemoglobin and it binds to
hemoglobin in red blood cells and is
delivered to body cells as blood circulates
in the body.
 Minerals
Calcium, and other minerals, is an
important component of bones and is
involved with muscle and nerve
functions and they serve as cofactors for
enzymes.
Magnesium is an important component
of the green pigment, chlorophyll,
involved in photosynthesis.
 Summary
Carbon compounds are the basic
building blocks of living organisms.
Biological macromolecules are
formed by joining of small carbon
compounds into polymers.
There are four types of biological
macromolecules; carbohydrates,
proteins, lipids, and nucleic acids
Summary
Monosaccharides undergo
condensation to form disaccharides
and poly saccharides through the
glycosidic linkages
Peptide bonds join amino acids in
proteins.
Lipids are esters of fatty acids and
alcohols
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