1. DNA the GENE
5. Discovery of DNA Frederick Griffith
Was studying Streptococcus Pneumonia
Smooth vs. Rough Strains
Smooth had a mucous coat and were pathogenic (caused pneumonia)
Rough were non-pathogenic
Conducted an experiment with mice
Found out that the Rough bacteria became transgenic with the Smooth and killed the mouse
7. Discovery of DNA Avery, McCarty and MacLeod
What was the genetic material in Griffith’s experiment?
Purified the heat–killed S-bacteria
Into DNA, RNA, and Protein
Mixed each with the R cells to see which one transformed
8. 3. Meselson-Stahl demonstrate the Semiconservative Replication� of DNA using radioactive nitrogen
10. Discovery of DNA Hershey-Chase Experiment
Studied viruses that infect bacterial cells called Bacteriophages
Viruses use Bacteria to multiply
Protein or DNA responsible for multiplying within the bacteria
Tagged the Protein with radioactive S
Why?
Tagged the DNA with radioactive P
Why?
Checked the Virus Progeny for Radioactive Elements
12. 1. Griffith Experiment demonstrates the Transformation of bacteria : DNA is later found to be the transforming principle
13. 2. Hershey-Chase demonstrate DNA is hereditary material not� proteins by using radioactive isotopes
14. 3. Meselson-Stahl demonstrate the Semiconservative Replication� of DNA using radioactive nitrogen
15. From Chromosomes to Genes
16. From Chromosomes to Genes
17. The Structure of DNA:�a double helix? Chargaff’s Nucleic Acid Ratios
Measured the base compositions of several species
Percentage of each base present
Human DNA
A = 30% and T = 29%
G = 20% and C = 19%
18. Rosalind Franklin and Maurice Wilkins use X-Ray diffraction to view structure
Watson and Crick propose a double helix using their X-Ray pictures The Structure of DNA:�a double helix?
19. DNA Helix
20. DNA Structure Watson and Crick propose a double helix and construct a model of DNA based on an accumulation of various researchers.
21. James and Francis
22. DNA Basic Composition DNA is made up of nucleotides
Nucleotides are made of
…………...Deoxyribose sugar
……………Phosphate
……………Base
bases are guanine,cytosine, thymine and adenine
23. DNA: The Deoxyribose Sugar
24. DNA: The Phosphate
25. DNA: The Nitrogenous Bases Purines
Adenine and Guanine
Double Ring Structure
Pyrimidines
Thymine and Cytosine
Single Ring Structure
26. DNA CANDY LABDNA CANDY LAB
28. Why do they pair up? Double helix had a uniform diameter
Purine + Purine
= too wide
Pyrimidine + Pyrimidine
= too narrow
Purine + Pyrimidine
= fits the x-ray data
29. DNA Double Helix
30. How does it know to pair up? ADENINE ALWAYS PAIRS WITH THYMINE
Two hydrogen bonds
GUANINE ALWAYS PAIRS WITH CYTOSINE
Three hydrogen bonds
31. Purines Adenine
Guanine
All double ring structures
32. �DNA BASE PAIRS
33. Pyrimidines Cytosine
Thymine
single ring
34. DNA Structure
35. Single stranded
37. DNA STRUCTURE
38. One last look
39. DNA Replication
41. Why must DNA Replicate? Species Survival
DNA must replicate BEFORE cell division
Synthesis during Interphase
All genes must be present in the daughter cells
42. How does DNA Replicate? Hydrogen bonds break, forming bubbles
Enzymes unwind and unzip
Free nucleotides in the nucleus start process of complementary base pairing
Nucleotides are fused together by DNA Polymerase only 5’ to 3’
Results in two identical double helixes
43. How does DNA Replicate?
44. How does DNA Replicate?
45. DNA and RNA functions Replication, Transcription, and Translation
46. �replication
47. Replication Steps Leading Strand DNA helicase uncoils and unzips exposing the DNA .
Single stranded binding proteins hold them apart.
Topoisomerase helps relieve strain on open strand
Primase adds RNA primer
DNA polymerase III adds free nucleotides
bases pair A-T and G-C as new strand is added in a 5’ to 3’ direction
48. Lagging strand is done in segments as each primer is added only after a coding segment is exposed. That means the end of it can not be replicated. Last primer only has a 5’ end .
Telomeres—ends of chromosomes have repeating nonsense sequences. TTAGGG
As cells age the ends shorten until it can no longer replicate the DNA
50. Proteins are critical Helicase-unwinds parental DNA
Single-strand binding protein-stabilize DNA strands
Primase-makes single RNA primers at 5’ end of the leading strand
DNA polymerases
I. Removes primer and replaces with DNA
III. Continuously synthesizes the leading strand and replaces it with DNA adding to 3’ end only
elongates each Okazaki fragment
51. Telomerase – replaces DNA nucleotides where RNA primer was located on the leading strand.
52. Lagging Strand Lagging strands begin with addition of Primase and then RNA primer
DNA polymerase I adds nucleotides in segments known as Okazaki Fragments
Ligase glues fragments together of lagging strand
53. Proofreading and Repairing DNA Mismatch repair –enzymes remove incorrectly paired nucleotides
Nuclease enzymes cut out damage
mutagens and carcinogens can cause these mismatches( uv light , x –rays, reactive chemicals)
Nucleotide excision repair
54. replication3
55. function of �DNA
56. RNA Nucleotides Made of the following:
………Ribose sugar
………Phosphate
one of four bases ( uracil replaces thymine)
57. Types of RNA M RNA- messenger RNA carries the DNA instructions(gene) out of nucleus to ribosome
tRNA-transfer RNA carries amino acids to their appropriate location during protein synthesis ( gene expression )
r RNA - ribosomal RNA makes up much of the ribosome and is essential to translation
58. Transcription in 3 steps 1. Initiation
RNA polymerase binds to promoter region
DNA unwinds and
2. Elongation polymerase initiates RNA synthesis one nucleiotide at a time 5’-3’
3.Termination- transcript released at terminator sequence
59. Eukaryotic Transcription Steps RNA polymerase II-binds to promoter regions mediated by proteins called transcription factors keys on upstreamTATA box with help of protein transcription factors-transcription initiation complex
DNA uncoils and exposes template-RNA nucleotides base pair with DNA template A-U, G-C via RNA polymerase
Elongation-nucleotides added to 3’ end of transcribed single strand
The sequence called polyadenylationAAUAAA-signals proteins to cut mRNA free
60. Prokaryotic Transcription RNA Polymerase binds to promoter region
Signal ends at Terminator sequence
RNA polymerase detaches several nucleotides down stream
61. Promoter Regions direct Transcription
62. Transcription
64. Termination AAATAAA- release mRNA
65. DNA Processing
66. Processing Genetic Material After transcription mRNA is PROCESSED
INTRONS ARE DELETED
A CAP 5’ end is capped with a modified guanine (G-p-p-p)
AND TAIL IS ADDED 50-250 nucleotides added to 3’ end( poly A tail AAA-AAA)
Introns are non coding units
Exons are expressed regions of RNA
67. RNA splicing cut and paste Small sequences at the end of each intron contain a signal for splicing.
snRNP’s – small nuclear ribonucleoproteins join together to form a SPLICEOSOME ---these release the introns and join the exons
alternative RNA splicing
Ribozymes- rna acts as an enzyme
68. Translation Steps Messenger RNA is at the ribosome and the tRNA nucleotides will base pair A-U, G-C
The tRNA has the amino acid attached to it and when it finds the right codon the RNA anticodon places the amino acids in their proper sequence for protein synthesis
The bond that forms between two amino caids is called a peptide bond.
………Base ( Uracil replaces Thymine)
70. Aminoacyl-tRNA syntase matches each amino acid to the correct tRNA
71. Steps in Translation 1. Initiation
2. Elongation-elongation factors enable addition of tRNAs to A site. codon recognition peptide bonds form
72. 3. translocation -tRNA move from A site to P site
4. Termination-UAA, UAG UGA stop the process
73. Polyribosomes- clusters of ribosomes translating the same mRNA�
76. Gene Expression Various cells express different genes
Organization of chromatin controls expression
Regulation of expressed genes occurs at each step
Control of transcription is most important regulatory mechanism ( binding factors and enhancers)
some binding factors are sensitive to hormones
77. Prokaryotic + gene control or feedback---- a metabolite or substrate causes gene to be expressed by acting as a transcription factor.
- neg. feedback the metabolite or substrate causes the removal of a blocking regulator
80. Key to lac operon inducible enzyme�Negative Feedback a. regulatory gene b. promoter c. operator d. structural genes e. operon f. RNA polymerase g. active repressor h. inducer metabolite lactose i. mRNA for variousenzymes to degrade lactose
83. Eukaryotic Gene Expression Heterochromatin to euchromatin-uncoiling and loss of DNA compaction
Attachment of acetyl groups to histone proteins
Metylation of DNA makes it unable to be expressed
84. 2. Transcriptional control Promoter region where a transcription initiator complex( including RNA polymerase II ) must bind.
General Transcription factors bind to RNA polymerase, this may be facilitated by binding specific transcription factors
Proximal Control elements
Distal Control elements-enhancers—bend in DNA
85. 3. Post-transcriptional Control Processing- alternative exon splicing
can produce a variety of genes
mRNA degradation-nuclease hydrolysis
Micro RNA complimentary binds and blocks m RNA transcript
Binding proteins can attach to mRNA and prevent translation
86. Protein Processing Polypeptides can be cleaved or groups attached, and quaternary structure will result in additional folding
Proteins can be degraded
Selective Transport
87. Transposons Stretches of DNA that can move from one location to another ( Jumping genes)
89. DNA TECHNOLOGIES SEQUENCING-determine order of bases
PCR (polymerase chain reaction)-makes repeated copies of desired DNA
RFLPS(restriction fragment length polymorphs) -unique gene fragments used as a fingerprint
Gel Electrophoresis- separate DNA by size on a gel bed
Probes- Radioactive tags label DNA
90. PCR-polymerase chain reaction Makes several copies of DNA
adjust temperature and enzyme
addition of nucleotides with DNA polymerase
95. Prepare single strand complimentary DNA
96. Mix hybrid (Known fragment as Hybrid )
97. Hybrid 3
98. Blot on Nylon Film
99. Use probe to identify position of gene on a chromosome
101. Reverse Transcriptase Viral enzyme
transcribes DNA from RNA
if you know the protein you can dtermine the mRNA which makes the protein
revers the transcription process to make DNA
103. Sequencing Methods Chain termination- Sanger Method
Restriction enzymes specific
Restriction fragments vary in size
gel electrophoresis resolves the fragments
104. Chain Termination Method-uses dedeoxynucleotides that terminate the synthesis of DNA strands at specific bases
105. Electrophoresis
106. Restriction Analysis
107. RFLP restriction fragment length polymorph
108. RFLPS Restriction fragments are created by cutting DNA with enzymes that cut at specific locations and create fragments of various size. These fragments can then be amplified and separated by gel electrophoresis
109. DNA Fingerprints
111. VNTRvariable number tandem repeats
112. Restriction Analysis
117. Other Technologies Recombinant DNA - gene splicing
Transgenic organism- an organism that contains another organism’s DNA
118. Recombinant DNA Plasmid DNA
Ligase enzyme Bacterial Cell
Restriction Enzyme Bacterial cell wall
Host cell Sticky ends
Vector
DNA fragment desired gene to be cloned
125. Transgenic Organism
127. Genetic Research has created a wealth of information
