biochemistry | anatomy honors
Biochemistry Basics
Chemistry Review
an element can be divided.
Atoms are the smallest particle into which
the number of neutrons, not in the number of protons.
Isotopes differ from each other in
Chemical Bonds
become ions by gaining or losing electrons.
IONIC bonds are formed when atoms
There are 2 types of ions:
Cations = positive ions formed by losing electrons. (Ex) Na+
Anions = negative ions formed by gaining electrons. (Ex) Cl-Anions are named using the ending “-ide”. For example, the anion of chlorine is called chloride.
Chemical Bonds
COVALENT Bondsform when atoms share electrons. Covalent bonds are more common than ionic bonds in the molecules of living organisms.
POLAR Covalent Bond→ electrons are unequally shared by the atoms and spend more time close to one atom than the
other. As a result, slightly positive (δ+) and slightly negative (δ–) charges develop in different parts of the molecule.
NONPOLAR Covalent Bond →forms between two atoms of the same element, or between atoms of different elements that share electrons more or less equally.
(Ex) O2
Chemical Bonds
Hydrogen Bonds form because
and water molecules in particular form lots of them. Individual
hydrogen bonds are weak and
easily broken, but many hydrogen bonds together can be very strong!
hydrogen (δ+) is attracted to any neighboring negative charges. Hydrogen bonds are common,
Chemical Bonds
van der Waals forces →Simple atom Simple atom Weak forces of attraction
between electrically neutral
molecules that collide with or
pass very close to each other.
Simple atom Simple atom The van der Waals force is
caused by temporary 5 nm attractions between electron- or less
rich regions of one molecule When 2 atoms come w/in 5 nm of each other, there and electron-poor regions of will be a slight interaction between them, thus
another. causing polarity and a slight attraction.
How do various bonds work in a cell?
“Both strong and weak bonds play key roles in the chemistry of our cells and bodies.
For instance, strong covalent bonds hold together the chemical building blocks that make up a strand of DNA. However, weaker hydrogen bonds hold together the two strands of the DNA double helix. These weak bonds keep the DNA stable, but also allow it to be opened up for copying and use by the cell.
More generally, bonds between ions, water molecules, and polar molecules are constantly forming and breaking in the watery environment of a cell. In this setting, molecules of different types can and will interact with each other via weak, charge-based attractions. For instance, a Na+ might interact with a water molecule in one moment, and with the negatively charged part of a protein in the next moment.”
Both strong and weak bonds play a key role in the folding of PROTEINS!
Khan Academy
WATER
Water is able to dissolve 1000’s of
substances because it is POLAR
→slightly charged on each end.
Water covers more than 75% of
the Earth’s surface. It is the most
abundant compound in nearly all
living things!
Opposites attract!
Hydrogen Bonding
because it is POLAR.
Water is “sticky”
property of
COHESION
in the
This results
and …
ADHESION
Adhesion allows for the property
of CAPILLARY ACTION which allows blood to move through small vessels!
Water can
defy gravity!
What does CAPILLARY ACTION
have to do with the HUMAN BODY?
Water is the
“universal solvent”
due its property
of ADHESION →
Water is attracted to
other polar molecules too!
_____ tonic _____ tonic
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2. 3.
A BUFFER is a solution that can maintain a nearly constant pH when Compound that releases Compound that releases
hydrogen ions (H+) into solution hydroxide ions (OH-) into solution
diluted, or when strong acids or bases are added.
Organic Chemistry EX: Water, Minerals (Calcium phosphate/bone)
Compounds that do not contain carbon
INORGANIC Compounds
ORGANICCompounds
EX: Carbohydrates, Lipids, Proteins, Nucleic Acids
Six most common elements in organic molecules:
C - H - O - N - P - S
Compounds that docontain carbon (except CO2)
CARBON is so special!
Can also form double bonds,
triple bonds, chains, and
rings.
Can form 4 single covalent
bonds; these bonds are
strong and stable.
Polymerization
Polysaccharides, Proteins, and
Nucleic acids are all polymers.
These molecules, in addition to
Lipids, are macromolecules.
(ATP & GTP are nucleoside
triphosphates that contain ribose.)
Chemical process that combines
several monomers to form a
polymer.
Dehydration Synthesis
Carbohydrates
General formula
is C(H2O)n
Sugars, starches,
cellulose
High Energy!
Glucose is made up of 6 Carbon atoms, 12 Hydrogen atoms, and 6 Oxygen atoms. The bonds present are COVALENT BONDS!
Aldehyde Aldehyde
Ketone
C6H12O6 C6H12O6 C6H12O6
Glucose is made up of 6 Carbon atoms, 12 Hydrogen atoms, and 6 Oxygen atoms. The bonds present are COVALENT BONDS!
1, 5 ether linkage
AP Bio
made?
How are
disaccharides
Polysaccharides: Starch/Glycogen
Mouth Salivary Amylase
Pancreatic Duodenum
Disaccharides
Maltose Sucrose Lactose
Small Maltase Sucrase Lactase Brush Intestine Border
Monosaccharides
2 Glucose 1 Glucose 1 Glucose AP Bio
1 Fructose 1 Galactose Does this model represent Dehydration Synthesis?
Hydrolysis
Lipids
Fats, oils, and waxes.
Lipids are compounds
made up of C, H, and
O, but often P and N.
Lipids:
o Store energy
o Form biological membranes
o Some hormones are lipids
AP Bio
What process is represented here?
closely together.
This makes
unsaturated fats
liquid at room
temperature.
Unsaturated fats
have kinks in their
hydrocarbon tails;
therefore they
cannot pack as
Oil is NONPOLAR
• Water is POLAR
OIL
“Like” dissolves “like”
WATER AP Bio Why would that be
very important in
living things?
Types of Lipids based on Structure Triglyceride
Phospholipid
| Wax | Steroid To be specific,
cholesterol is a sterol or a steroid with an –OH group | | --- | --- |
Importance of Cell Membrane Structure!
Proteins
Organic compounds composed
mainly of C, H, O, and N.
Proteins are polymers of
AMINO ACIDS, joined together
by peptide bonds.
All amino acids have a similar
chemical structure, but differ
in a region of the molecule
known as an R group.
DISULPHIDE BONDS
Disulphide bonds occur in proteins, not amino acids, although they involve a covalent bond between two amino acids (both cysteine). Disulphide bonds are used as extra stabilization of the structure of proteins. They are very important in determining the quaternary structure of some proteins. (EX) Role of disulfide bonds in the structure of antibody molecules.
Proteins have MANY ROLES!
Help carry out chemical reactions by serving as enzymes.
Used in forming disease–fighting antibodies.
Provides energy if carbohydrate and fat are in short
Play a structural role – cytoskeleton - The skin and supply.
muscles of animals are made mostly of proteins.
Pump small molecules in/out of cells by serving as permeases.
Serve as chemical messengers called hormones.
Enzymes
Effect of Temperature and pH on Enzymes Key Words: Denature; Optimum pH
Key Words: Denature; Optimum pH
TEMPERATURE
pH
Temperature increase speeds up Changes in pHwill also denature
enzyme-controlled reactions, but the enzyme by changing the shape
only to a point ... of the enzyme. Enzymes are also
When heated TOO much, enzymes adapted to operate at a specific
(since they are dependent on pH or pH range (Optimum pH).
their shape) become denatured.
Interpret
Graph
This
(Mouth)
(Stomach)
(Kidney)
Nucleic Acids• Very large and complex
organic molecules that
store important
information in the cell.
Polymers of nucleotides.
There are 2 Basic Kinds:
DNA and RNA.
DNA
Deoxyribonucleic Acid
▪All living things are based
on a universal genetic code
▪Responsible for storing,
copying, and transmitting
the genetic information in deoxyribose
a cell
▪Found in the nucleus
Types of RNA
▪Messenger RNA (mRNA) - Carries instructions for protein synthesis (translation) from the nucleus to ribosomes in the cytoplasm.
▪Transfer RNA (tRNA)- Carries amino acids to the ribosome and matches them to the coded mRNA message during translation.
▪Ribosomal RNA (rRNA)- Forms an important part of both subunits of the ribosome
Transcription: DNA → mRNA
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