1. Ch 4 Molecular Basis of Living Organisms

2. After water, cells consists mostly of carbon-based compounds= organic molecules
Examples
Carbohydrates, lipids, proteins, nucleic acids (DNA, RNA)

3. Carbon Bonds Consequence:
Four valence electrons--> allows 4 covalent single bonds
Or 2 double bonds
Consequence:
Potential to form complex molecules

4. Molecular Formula Structural Formula Ball-and-Stick Model
Space-Filling
Model
Methane
Ethane
Ethene (ethylene)

5. Shape of carbon complex
Tetrahedron
When C bonded to 4 other groups
Groups can rotate around single bonds
Linear/Flat/Planar
When C is double bonded to another C
Unable to rotate

6. Common Carbon Bonding Partners in Biological Molecules
Hydrogen
Oxygen
Nitrogen

7. Molecular Diversity of Organic Molecules
Due in part to
Formation of carbon chain
Differences in length and organization of chain

8. (commonly called isobutane)
Ethane
Propane
Length
Butane
2-methylpropane
(commonly called isobutane)
Branching
1-Butene
2-Butene
Double bonds
Note: molecular
abbreviation
Cyclohexane
Benzene
Rings

9. Isomers different covalent arrangements of atoms
Compounds with same molecular formula but different structures/ properties
Structural isomers
different covalent arrangements of atoms
Geometric isomers
same covalent arrangements;different spatial arrangements
Enantiomers
mirror images of each other

10. Structural isomer Geometric Enantiomers Stereoisomers Mirror images
LE 4-7
Structural isomer
Structural isomers differ in covalent partners, as shown in this example of two isomers of pentane.
Geometric
cis isomer: The two Xs
are on the same side.
trans isomer: The two Xs
are on opposite sides.
Geometric isomers differ in arrangement about a double bond. In these diagrams, X represents an atom or group of atoms attached to a double-bonded carbon.
Enantiomers
Stereoisomers
Mirror images
L isomer
D isomer
Enantiomers differ in spatial arrangement around an asymmetric carbon, resulting in molecules that are mirror images, like left and right hands. The two isomers are designated the L and D isomers from the Latin for left and right (levo and dextro). Enantiomers cannot be superimposed on each other.

11. Enantiomers (effective against Parkinson’s disease) (biologically
LE 4-8
Enantiomers
L-Dopa
(effective against
Parkinson’s disease)
D-Dopa
(biologically
Inactive)

12. Functional Groups
Molecules attached to carbon chains that are involved in reactions
Determine distinctive properties of organic molecule

13. LE 4-9
Estradiol
Female lion
Testosterone
Male lion

14. The six functional groups that are most important in the biological chemistry:
Hydroxyl group
Carbonyl group
Carboxyl group
Amino group
Phosphate group
Sulfhydryl group

15. FUNCTIONAL PROPERTIES
LE 4-10aa
STRUCTURE
Ethanol, the alcohol present in
alcoholic beverages
NAME OF COMPOUNDS
FUNCTIONAL PROPERTIES
Alcohols (their specific names
usually end in -ol)
polar as a result of the
electronegative oxygen atom
drawing electrons toward itself.
Attracts water molecules, helping
dissolve organic compounds such
as sugars

16. STRUCTURE EXAMPLE NAME OF COMPOUNDS Acetone, the simplest ketone
LE 4-10ab
Acetone, the simplest ketone
STRUCTURE
EXAMPLE
Acetone, the simplest ketone
Propanal, an aldehyde
NAME OF COMPOUNDS
Ketones if the carbonyl group is
within a carbon skeleton
FUNCTIONAL PROPERTIES
Aldehydes if the carbonyl group is
at the end of the carbon skeleton
A ketone and an aldehyde may
be structural isomers with
different properties, as is the case
for acetone and propanal.

17. LE 4-10ac
STRUCTURE
EXAMPLE
Acetic acid, which gives vinegar
its sour taste
NAME OF COMPOUNDS
FUNCTIONAL PROPERTIES
Carboxylic acids, or organic acids
Has acidic properties because it is
a source of hydrogen ions.
The covalent bond between
oxygen and hydrogen is so polar
that hydrogen ions (H+) tend to
dissociate reversibly; for example,
Acetic acid
Acetate ion
In cells, found in the ionic form,
which is called a carboxylate group.

18. LE 4-10ba
STRUCTURE
EXAMPLE
Glycine
Because it also has a carboxyl
group, glycine is both an amine and
a carboxylic acid; compounds with
both groups are called amino acids.
NAME OF COMPOUNDS
FUNCTIONAL PROPERTIES
Amine
Acts as a base; can pick up a
proton from the surrounding
solution:
(nonionized)
(ionized)
Ionized, with a charge of 1+,
under cellular conditions

19. STRUCTURE EXAMPLE NAME OF COMPOUNDS
LE 4-10bc
STRUCTURE
EXAMPLE
Glycerol phosphate
NAME OF COMPOUNDS
FUNCTIONAL PROPERTIES
Organic phosphates
Makes the molecule of which it
is a part an anion (negatively
charged ion).
Can transfer energy between
organic molecules.

20. STRUCTURE EXAMPLE NAME OF COMPOUNDS
LE 4-10bb
STRUCTURE
EXAMPLE
(may be written HS—)
Ethanethiol
NAME OF COMPOUNDS
FUNCTIONAL PROPERTIES
Thiols
Two sulfhydryl groups can
interact to help stabilize protein
Structure.

21. LE 4-10bc
Cccccccccc
ccccccc
ccc
PO4_
COOH
Questions? OH SH

22. Ch 5 Overview: The Molecules of Life
Within cells
small organic molecules bond together to form larger molecules
Macromolecules
large molecules composed of thousands of covalently connected atoms

23. long molecule consisting of similar building blocks called monomers
What is the structure of most organic macromolecules?
Polymer
long molecule consisting of similar building blocks called monomers
Three of the four classes of life’s organic molecules are polymers:
Carbohydrates
Proteins
Nucleic acids

24. LE 5-2
Short polymer
Unlinked monomer
Dehydration removes a water
molecule, forming a new bond
Longer polymer
Dehydration reaction in the synthesis of a polymer
Hydrolysis adds a water
molecule, breaking a bond
Hydrolysis of a polymer

25. The Synthesis and Breakdown of Polymers
Synthesis (Construction)
Monomers link together through
dehydration reactions (aka condensation rxn)
Breakdown
Polymers disassemble into monomers by
hydrolysis (reverse of dehydration)

26. Carbohydrates Functions Fuel Construction and support
Structure
Simple sugars: monosaccharides
Formula (CH2O)n
Polymers
Disaccharides (relatively short)
Polysaccharides (long)

27. Monosaccharides

28. Triose sugars (C3H6O3) (C5H10O5) Hexose sugars (C5H12O6)
LE 5-3
Triose sugars
(C3H6O3)
Pentose sugars
(C5H10O5)
Hexose sugars
(C5H12O6)
Aldoses
Glyceraldehyde
Ribose
Glucose
Galactose
Ketoses
Dihydroxyacetone
Ribulose
Fructose

29. Structures Monosaccharides Functions linear ---> ring
major fuel for cells
raw material for building larger molecules
Structures
linear ---> ring

30. LE 5-4
Glucose
Linear and
ring forms
Abbreviated ring
structure

31. Disaccharide Nomenclature of bond glycosidic linkage
forms by a dehydration reaction between two monosaccharides
Nomenclature of bond
glycosidic linkage

32. Disaccharide formation
LE 5-5
Disaccharide formation
Dehydration
reaction in the
synthesis of maltose
1–4
glycosidic
linkage
Glucose
Glucose
Maltose
Dehydration
reaction in the
synthesis of sucrose
1–2
glycosidic
linkage
Glucose
Fructose
Sucrose

33. Polysaccharides

34. Storage Polysaccharides
Fuel storage molecule in plants
Polymer of glucose-->Starch
-glycosidic linkage
Stored in chloroplasts and other plastids

35. What kind of isomer is this? Geometric LE 5-7 Glucose  Glucose
and  glucose ring structures
Geometric
Starch: 1–4 linkage of  glucose monomers.
Cellulose: 1–4 linkage of  glucose monomers.

36. Starch: a plant polysaccharide
LE 5-6a
Chloroplast
Starch
1 µm
Amylose
Amylopectin
Starch: a plant polysaccharide

37. Glycogen storage polysaccharide of glucose in ANIMALS
Stored in liver and muscle

38. Glycogen: an animal polysaccharide
LE 5-6b
Mitochondria
Glycogen granules
0.5 µm
Glycogen
Glycogen: an animal polysaccharide

39. Structural Polysaccharides
Cellulose found in plant cell walls
Polymer of glucose
-glycosidic linkages

40. alpha Starch beta Cellulose LE 5-7 Glucose  Glucose
and  glucose ring structures
alpha
Starch
Starch: 1–4 linkage of  glucose monomers.
beta
Cellulose
Cellulose: 1–4 linkage of  glucose monomers.

41. Structural difference of glucose isomers
Polymers of alpha glucose
helical
Polymers with beta glucose
Straight
Pack together well in microfibrils
Stabilized by H-bonds
Strong

42. Cellulose microfibrils in a plant cell wall
LE 5-8
Cellulose microfibrils
in a plant cell wall
Cell walls
Microfibril
0.5 µm
Plant cells
Cellulose
molecules
b Glucose
monomer

43. -unable to breakdown cellulose -lack hydrolytic enzymes
Many animals
-unable to breakdown cellulose
-lack hydrolytic enzymes
-insoluble fiber results
Some bacteria
Possess enzymes to breakdown cellulose
Live in symbiotic relationship in guts of animals (from cow to termite)

45. Chitin structural polysaccharide in the exoskeleton of arthropods
cell walls of many fungi
used as surgical thread!

47. Assignment Due Friday
1. Bring to class a substance made of or containing a carbohydrate.
2. Identify the carbohydrate and do research on its structure, function and uses. Find reliable sources on Google and various science databases like PubMed. Provide a short typed description properly citations.