1. Nucleic acids

2. Nucleic Acids
Information storage

3. Nucleic Acids-C,H,O,N,P Function: genetic material stores information
genes
blueprint for building proteins
DNA  RNA  proteins
transfers information
blueprint for new cells
blueprint for next generation
DNA
proteins

4. A T C G
Isn’t this a great illustration!?

5. Nucleic Acids Examples: Structure: RNA (ribonucleic acid)
single helix
DNA (deoxyribonucleic acid)
double helix
Structure:
monomers = nucleotides
DNA
RNA

6. Nitrogen base I’m the A,T,C,G or U part!
Nucleotides
3 parts
nitrogen base (C-N ring)
pentose sugar (5C)
ribose in RNA
deoxyribose in DNA
phosphate (PO4) group
Nitrogen base I’m the A,T,C,G or U part!
DNA & RNA are negatively charged:
Don’t cross membranes.
Contain DNA within nucleus
Need help transporting mRNA across nuclear envelope.
Also use this property in gel electrophoresis.

7. Types of nucleotides 2 types of nucleotides different nitrogen bases
Purine = AG
Pure silver!
2 types of nucleotides
different nitrogen bases
purines
double ring N base
adenine (A)
guanine (G)
pyrimidines
single ring N base
cytosine (C)
thymine (T)
uracil (U)

8. Nucleic Acids Nitrogeneous bases can be:
Purines (Adenine and Guanine) ~ double-ring
Pyrimidines (Cytosine, Thymine and Uracil)
~ single-ring

9. Dangling bases? Why is this important?
Nucleic polymer
Backbone
sugar to PO4 bond
phosphodiester bond
new base added to sugar of previous base
polymer grows in one direction
N bases hang off the sugar-phosphate backbone
Dangling bases? Why is this important?

10. Deoxyribonucleic acid (DNA)
Nitrogen base attached to sugar at C-1
Phosphate attached to sugar at C-5
Phosphate attached to next nucleoside at C-1 by phosphodiester linkage
Each strand has a 3’ and 5’ end

11. Pairing of nucleotides
Nucleotides bond between DNA strands
H bonds
purine :: pyrimidine
A :: T
2 H bonds
G :: C
3 H bonds
The 2 strands are complementary.
One becomes the template of the other & each can be a template to recreate the whole molecule.
Matching bases? Why is this important?

12. H bonds? Why is this important?
DNA molecule
Double helix
H bonds between bases join the 2 strands
A :: T
C :: G
H bonds = biology’s weak bond
• easy to unzip double helix for replication and then re-zip for storage
• easy to unzip to “read” gene and then re-zip for storage
H bonds? Why is this important?

13. Deoxyribonucleic acid (DNA) Complementary strands
H bonds ~ between paired bases
van der Waals ~ between stacked bases

14. Matching halves? Why is this a good system?
Copying DNA
Replication
2 strands of DNA helix are complementary
have one, can build other
have one, can rebuild the whole
when cells divide, they must duplicate DNA exactly for the new “daughter” cells
Why is this a good system?
Matching halves? Why is this a good system?

15. Deoxyribonucleic acid (DNA)
Strands run antiparallel

16. When does a cell copy DNA?
When in the life of a cell does DNA have to be copied?
cell reproduction
mitosis
gamete production
meiosis
when cells divide, they must duplicate DNA exactly for the new “daughter” cells
Why is this a good system?

17. DNA replication
“It has not escaped our notice that the specific pairing we have postulated immediately suggests a possible copying mechanism for the genetic material.”
James Watson
Francis Crick
1953
The greatest understatement in biology!

18. Watson and Crick … and others…
1953 | 1962
Watson and Crick … and others…
Proposed the structure of DNA.
1962 – won the Nobel Prize with Wilkins.
Discovered & published in 1953
Nobel Prize in 1962:
Watson, Crick, Wilkins

19. Rosalind Franklin ( )
A chemist by training, Franklin had made original and essential contributions to the understanding of the structure of graphite and other carbon compounds even before her appointment to King's College. Unfortunately, her reputation did not precede her. James Watson's unflattering portrayal of Franklin in his account of the discovery of DNA's structure, entitled "The Double Helix," depicts Franklin as an underling of Maurice Wilkins, when in fact Wilkins and Franklin were peers in the Randall laboratory. And it was Franklin alone whom Randall had given the task of elucidating DNA's structure. The technique with which Rosalind Franklin set out to do this is called X-ray crystallography. With this technique, the locations of atoms in any crystal can be precisely mapped by looking at the image of the crystal under an X-ray beam. By the early 1950s, scientists were just learning how to use this technique to study biological molecules. Rosalind Franklin applied her chemist's expertise to the unwieldy DNA molecule. After complicated analysis, she discovered (and was the first to state) that the sugar-phosphate backbone of DNA lies on the outside of the molecule. She also elucidated the basic helical structure of the molecule.
After Randall presented Franklin's data and her unpublished conclusions at a routine seminar, her work was provided - without Randall's knowledge - to her competitors at Cambridge University, Watson and Crick. The scientists used her data and that of other scientists to build their ultimately correct and detailed description of DNA's structure in Franklin was not bitter, but pleased, and set out to publish a corroborating report of the Watson-Crick model. Her career was eventually cut short by illness. It is a tremendous shame that Franklin did not receive due credit for her essential role in this discovery, either during her lifetime or after her untimely death at age 37 due to cancer.

20. Interesting note… Ratio of A-T::G-C affects stability of DNA molecule
2 H bonds vs. 3 H bonds
biotech procedures
more G-C = need higher T° to separate strands
high T° organisms
many G-C
parasites
many A-T (don’t know why)
At the foundation of biology is chemistry!!

21. Another interesting note…
ATP Adenosine triphosphate
modified nucleotide
adenine (AMP) + Pi + Pi + +

22. Ribonucleic acid (RNA)
Ribose sugar
Nitrogeneous bases:
A, C, G, and U
SINGLE STRANDED

23. RNA RNA functions in protein synthesis. There are three types of RNA:
Messenger RNA (mRNA) ~ blueprint for construction of a protein.
Ribosomal RNA (rRNA)
~ construction site where the protein is made.
Transfer RNA (tRNA)
~ truck delivering the proper amino acid to the site at the right time.

24. Deoxyribonucleic acid (DNA) Ribonucleic acid (RNA)
DNA → RNA → protein

25. Information in Biology
Biological systems process matter, energy, and information.
The information directs the construction of proteins.
This is known as the “Central Dogma” of molecular biology.
It will be the underpinning of most biological advances during your lifetime.

26. Macromolecule Review

27. Carbohydrates Structure / monomer Function Examples monosaccharide
energy
raw materials
energy storage
structural compounds
Examples
glucose, starch, cellulose, glycogen
glycosidic bond

28. Lipids Structure / building block Function Examples
glycerol, fatty acid, cholesterol, H-C chains
Function
energy storage
membranes
hormones
Examples
fat, phospholipids, steroids
ester bond (in a fat)

29. Proteins Structure / monomer Function Examples amino acids
levels of structure
Function
enzymes u defense
transport u structure
signals u receptors
Examples
digestive enzymes, membrane channels, insulin hormone, actin
peptide bond

30. Nucleic acids Structure / monomer Function Examples nucleotide
information storage & transfer
Examples
DNA, RNA
phosphodiester bond

31. Ghosts of Lectures Past (storage)

32. Building the polymer

33. RNA & DNA RNA DNA single nucleotide chain double nucleotide chain
N bases bond in pairs across chains
spiraled in a double helix
double helix 1st proposed as structure of DNA in 1953 by James Watson & Francis Crick (just celebrated 50th anniversary in 2003!)

34. Passing on information? Why is this important?
Information polymer
Function
series of bases encodes information
like the letters of a book
stored information is passed from parent to offspring
need to copy accurately
stored information = genes
genetic information
All other biomolecules we spoke about served physical or chemical functions. DNA & RNA are information storage molecules.
DNA well-suited for an information storage molecule:
chemically stable
stores information in the varying sequence of nucleotides (the genetic code)
its coded sequence can be copied exactly by the synthesis of complementary strands; easily unzipped & re-zipped without damage (weak H bonds)
damage to one strand can be repaired by addition of bases that match the complementary strand
Passing on information? Why is this important?