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Chapter 4: Life is based on molecules with carbon (organic molecules). organic compounds isomers functional groups. Much of the chemistry of life is based on organic compounds. organic compounds have at least one carbon atom covalently bound to either: another carbon atom or to hydrogen - PowerPoint PPT Presentation
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Chapter 4: Life is based on molecules with carbon (organic molecules)
organic compounds isomers functional groups
.
Much of the chemistry of life is based on organic compounds
organic compounds have at least one carbon atom covalently bound to either:
another carbon atom or to hydrogen
the chemistry of organic molecules is organized around the carbon atom
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• Discuss the chemistry of carbon. How does it typically bond? What does it typically bond to? What sort of shapes, angles, freedoms, etc. are associated with the bonds that it makes?
• Draw a tetrahedron.
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Organic Compounds carbon atoms have six electrons –
2 in level 1 4 in their valence (outer) shell (level 2) carbon is not a strongly electron seeking element,
and it does not readily give up its electrons; therefore:
carbon does not readily from ionic bonds it almost always forms covalent bonds
carbon can form up to 4 covalent bonds (and typically does form all four)
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Organic Compounds
wide diversity in organic compounds over 5 million identified variety partially because carbon tends to
bond to carbon, hydrogen, oxygen, nitrogen, sulfur, and phosphorus
hydrocarbons – contain only hydrogen and carbon
single carbon-carbon bonds allow rotation around them and lend flexibility to molecules
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Organic Compounds building of organic macromolecules also leads to
diversity carbon works well as a molecular “backbone” for forming
long chain molecules stronger carbon-carbon bonds can be made with double and
triple covalent bonds carbon chains can branch
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Organic Compounds the shape of a molecule is important in
determining its chemical and biological properties
When 4 separate bonds are formed by carbon…
formed at 109.5 degree angles form a pyramid with a triangular
base called a tetrahedron
When double bonds are formed… angles are 120 or 180 degrees apart,
and they all lie in the same plane
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Organic Compounds
bond angles for carbon play a critical role in determining the shape of molecules
generally there is freedom to rotate around carbon to carbon single bonds but not double (or triple) bonds
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• Discuss the chemistry of carbon. How does it typically bond? What does it typically bond to? What sort of shapes, angles, freedoms, etc. are associated with the bonds that it makes?
• Draw a tetrahedron.
.
Chapter 4: Life is based on molecules with carbon (organic molecules)
organic compounds isomers functional groups
.
• Discuss isomers. What are they? What is the difference between structural isomers and stereoisomers? Between cis-trans isomers and enantiomers?
• Draw an example of each of these:
structural isomers
cis-trans isomers
enantiomers
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• What type of isomer situation is this? How do you know?
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• What type of isomer situation is this? How do you know?
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• What type of isomer situation is this? How do you know?
.
• What type of isomer situation is this? How do you know?
.
• What type of isomer situation is this? How do you know?
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• What type of isomer situation is this? How do you know?
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Isomers
have the same molecular formula have different structures there are two kinds of isomers
structural isomers stereoisomers
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Isomers structural isomers - substances with the
same molecular formula that differ in the covalent arrangement of their atoms
example: ethanol and dimethyl ether (C2H6O)
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Isomers stereoisomers - substances with the same
arrangement of covalent bonds, but the order in which the atoms are arranged in space is different
two types: enantiomers and diastereomers
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Isomers cis-trans isomers – diastereomers associated with
compounds that have carbon-carbon double bonds since there is no rotation around the double bond the other
atoms attached to the carbons are stuck in place in relationship to each other
larger items together = cis; larger items opposite = trans examples: trans-2-butene and cis-2-butene
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Isomers enantiomers – substances that are mirror
images of each other and that cannot be superimposed on each other
sometimes called optical isomers (kind of a loose term, though)
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Isomers typically, only one form of an enatiomer pair is found in and/or
used by organisms the enantiomers are given designations such as
[(+)- vs. (−)-] or [D- vs. L-] or [(R)- vs. (S)-] biologically important enantiomers include
amino acids (found in proteins) – most are L-amino acids
(e.g. L-leucine, L-alanine, etc) sugars – most are D-sugars
(e.g. D-glucose, D-fructose, etc.)
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• Discuss isomers. What are they? What is the difference between structural isomers and stereoisomers? Between cis-trans isomers and enantiomers?
• Draw an example of each of these:
structural isomers
cis-trans isomers
enantiomers
.
Chapter 4: Life is based on molecules with carbon (organic molecules)
organic compounds isomers functional groups
.
• What is a functional group, and why is it useful to know them? Quiz each other on the names and chemistry of the functional groups in the notes.
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Functional Groups
functional groups determine most of the reactive properties (functions) of organic molecules
functional groups are groups of atoms covalently bonded to a carbon backbone that give properties different from a C-H bond
the properties of the major classes of organic compounds (carbohydrates, lipids, proteins, and nucleic acids) are determined mostly by their functional groups
learn the seven functional groups on the following slides
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Functional Groups
hydroxyl group: polar; found in alcohols
carbonyl group: polar; found in aldehydes and ketones
carboxyl group: weakly acidic; found in organic acids (such as amino acids)
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Functional Groups
amino group: weakly basic; found in such things as amino acids
sulfhydryl group: essentially nonpolar; found in some amino acids
phosphate group: weakly acidic; found in such things as phospholipids and nucleic acids
methyl group: nonpolar (thus hydrophobic); found in such things as lipids, other membrane components
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