Transcript Bio 101
Bio 160
Unit 1-2
Week One- Lecture Two
Writing Chemical Formulas
• 2 methods
– Molecular formula- shows the atoms and their
numbers, but not how they are bonded
• H2O, C6H12O6
– Structural formula- shows the atoms and their
numbers but also gives a “picture” or
structural map of how the atoms are bonded
together
• The sticks represent bonds
Organic Compounds
• Organic compounds are synthesized by
cells and contain carbon atoms
– Carbon has 4e- in outer shell, so has a high
affinity for bonding covalently
• Will bond in single or double bonds
– Hydrocarbons- compounds formed with only
carbon and hydrogen atoms
• Can create long chains of carbon or a carbon
skeleton
Organic Compounds
• Carbon skeleton can contain same number of
atoms but be shaped differently, creating an
isomer
– Each isomer, while made up of the same number of
atoms, has its own unique properties because of its
shape
Organic Compounds
– Functional groups- usually only certain areas
of an organic molecule participate in bonding.
That area is called a functional group
• 4 major functional groups important for sustaining
life
–
–
–
–
Hydroxyl- OH
Amino- NH2
Carbonyl- CO
Carboxyl- COOH
Organic Compounds
• All 4 groups are highly polar, making them
hydrophilic and soluble in water
– Water is essential for proper metabolic functioning and
this is why
• Many biological molecules may contain 2 or more
functional groups
Organic Compounds
– Macromolecules- huge organic chains of
molecules
• Polymers- large molecule consisting of many
similar or identical units
• Monomers- stick together to create polymers
– Polymers stick together to create macromolecules
– 40-50 common monomers, plus a few rare ones create
the multitude of different biological molecules
Organic Compounds
– Reaction types
• Dehydration synthesis: the creation of polymers by
linking an H of one monomer to an OH of another,
liberating water (H2O) in the process
• Hydrolysis: the breaking down of macromolecules
by adding water, breaking the bonds between
monomers, giving an OH on one and giving an H
to another
4 classes of macromolecules
necessary to life
• Carbohydrates
– Ranges from small sugar molecules to up to
long macromolecules
– Monosaccharides- simple sugars usually have
an –ose ending
• Some ratio of C : H2 : O
• Glucose C6H12O6
• Fructose isomer of glucose (has the same number
of atoms as glucose but arranged differently)
• Glucose is the key sugar for cellular E and the
necessary end product of the small intestine
digestive system
4 Classes of Macro…cont
– Disaccharides-double sugar
• Comes from the dehydration synthesis of 2
monosaccharide
• Most common is sucrose-table sugar
– Fructose + glucose = sucrose
– Polysaccharides- “many” sugars
• Starch- storage sugar- broken down as needed to
be released as glucose
– Can be hydrolyzed quickly by digestive system
4 Classes of Macro…cont
• Cellulose- forms cell walls of plants
– Most abundant compound on earth
– Closely resembles starch and glycogen but shaped
differently
» Fibrils lay side by side and are joined together by
hydrogen bonds, forming a tough, fibrous wall
» Supports plants and trees
– Cannot be hydrolyzed by animals unless they have
cellulose hydrolyzing microorganisms in their gut
» Does provide “roughage” in diet, but does not give
nutrition
4 Classes of Macro…cont
• Lipids- Fats
– Carbon- hydrogen chains
• Non-polar, therefore hydrophobic and will not
dissolve in water
– Fats are composed of glycerol molecule and a
fatty acid molecule
• 1 glycerol + 3 fatty acids = 1 triglyceride
• Body naturally manufactures triglycerides but when
you include too much fat in the diet, body makes
more than needed and gets stored in fat cells or
free floats in blood
– Genetic conditions may cause body to overproduce
triglycerides, increasing concentration in the blood
4 Classes of Macro…cont
– Unsaturated vs. saturated fats
• Fat molecules are chains of carbons
• How the H’s arrange around the C’s determines
whether fat is saturated or unsaturated
– Unsaturated have double bonds so not all C’s have H’s
surrounding them. Therefore the molecule cannot tightly
pack and can be “broken down” much easier in digestive
tract
» Remain liquid at room temperature
» Plant origins
4 Classes of Macro…cont
– Saturated fats contain no double bonds, so
every C has H’s around it, saturating it.
Molecule becomes tightly packed; hard to
break down in system and remains solid at
room temperature, mostly animal in origin
4 Classes of Macro…cont
– Phospholipids contain an atom of
phosphorous and have only 2 fatty acids
• Major component of cell membranes
• Hydrophobic, protects the cell
– Wax- 1 fatty acid linked to an alcohol
• Protect surfaces from drying out
– Steroids- form carbon rings (non anabolic)
• Cholesterol- steroid found in cell membranes and
used in the manufacture of other types of steroids
4 Classes of Macro…cont
• Proteins- made of chains of amino acids
– Several different classes of proteins
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•
•
•
•
•
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Structural- hair, tendon/ ligament fibers
Contractile- muscles
Storage- egg whites (food supply for embryos)
Defensive- antibodies
Transport- hemoglobin- carries O2
Signal-some hormones carry body messages
Enzyme- control rates of chemical reactions
without it being used or changed in any way
4 Classes of Macro…cont
– 20 amino acids make up all the different types
of proteins
• All amino acids contain an amino group, carboxyl
group and an R group
• 1
– It is the R group that makes each amino acid different
4 Classes of Macro…cont
– Amino acids linked by peptide bonds, where
the carboxyl group of one links with the amino
group N of another in dehydration synthesis,
creating the polypeptide bond.
– The shape of the protein determines its
function
• Primary shape- the sequence of amino acids
• When shape is altered, the functioning ability of the
protein is altered as well
– Denaturing- altering of protein
» Heat, radiation, freezing, pH, salt
4 Classes of Macro…cont
• Nucleic Acids– Deoxyribonucleic Acid
• Contains the genetic material or code of the
organism
– Determines what proteins need to be made and when.
• Made of Nucleotides
– A sugar (deoxyribose), a phosphate, and nitrogen base
(A, T, G, C)
• Shaped in a double helix- (double stranded spiral)one side is a compliment of the other
• Cannot leave the nucleus of the cell
– A-T G-C
Cells
Prokaryote cells vs. Eukaryotes
• Prokaryote cells are ancient cells and
have no organized nucleus. (Bacteria,
Archea)
– Its DNA is coiled into a nucleotide region but
is not differentiated with membrane
– Contain ribosomes, plasma membrane,
cytoplasm
– Some have a bacterial cell wall outside the
plasma membrane and others also have a
capsule for protection and adhesion.
– May also have pilli and prokaryotic flagella
Pro. Vs Euk. cont…
• Eukaryotic cells make up all other forms of
cells
• Evolved from prokaryotic cell relationships
– Have highly organized and specialized
organelles
Eukaryotic Cell Organelles (parts)
and functions in brief
• Not every cell has every organelle
– Plant and animal cells do differ in some ways
• Organelles
– General Manufacturing function
• Nucleus
• Ribosomes
• Rough endoplasmic reticulum (has ribosomes
attached)
• Smooth endoplasmic reticulum
• Golgi bodies (complex, apparatus)
Eukaryotic Cell Organelles cont…
– General breakdown function
• Lysosomes
• Peroxisomes (break down materials using
hydrogen peroxide H2O2)
• Vacuoles
– Energy Processing functions
• Mitochondria- found in both plant and animals
• Cholorplasts- found in plants and some protists
Eukaryotic Cell Organelles cont…
– Support, movement, communication functions
• Cytoskeleton
– Cilia, flagella, centrioles, microfilaments
• Cell wall- in plants
• Extracellular matrix- in animals
– Sticky glycoproteins
• Cell junctions
– Tight, anchoring, communication
– Plants- plasmodesmata (channels between plant cells)