DNA Structure and Replication
Lifespan Gene In The News
Chromosomes Contain all information for an organism Karyotype = arrangement of chromosomes
Eukaryotic Chromosomes Chromatin = –DNA –Histone proteins – condenses to form strands called chromosomes, –Strands occur just prior and during cell division
DNA Double stranded, coiled molecule
Discovery of Hereditary Material Friedrich Miescher (1869) –Isolates “nuclein” from nucleus – was not called DNA until the 1920’s –No notion it contained hereditary material Gregor Mendel (late 1800s) –Pioneering work in genetics –Traits are inherited discrete factors
Discovery of Hereditary Material Walter Sutton (early 1900s) –Suggested chromosomes held hereditary factors –No direct evidence for support Thomas Hunt Morgan (1910) –Provided experimental evidence to support Sutton –Identified X (sex) hormone – worked with chromosomes of fruit flies and eye color
Discovery of Hereditary Material Phoebus Levene (1920s) –Two types of nucleic acid in cells, composed of repeating nucleotides –Both types with nearly identical structures – DNA & RNA are the 2 types
Nucleotide Structure Three different components –Phosphate group –Nitrogen containing base (A,T,G,C,U) –Five-carbon sugar ( ribose or deoxyribose )
Nitrogen Containing Bases
Discovery of Hereditary Material Oswald Avery (early 1940s) –Preliminary evidence for DNA as hereditary material –Transformed bacteria by transferring DNA
Discovery of Hereditary Material Edwin Chargaff (late 1940s) –Proportion of bases varies in the DNA of different type organisms –Portions of bases roughly equal, (A=T & C =G) –Purines = pyrimidines (A + G = C + T)
Discovery of Hereditary Material George Beadle & Edward Tatum (1950s) –One-gene-one-enzyme theory –Enzyme production under control of genes Alfred Hershey & Martha Chase (1952) confirmed –Building of Avery’s work, confirmed DNA as hereditary material
Discovery of Hereditary Material Rosalind Franklin & Maurice Wilkins (1953) –Developed double helix model for DNA –Evidence from X-ray diffraction
Discovery of Hereditary Material James Watson & Francis Crick (1953) –Structure of DNA –Synthesized previous research –Nobel Prize in 1962, along with Wilkins, Franklin died before nominations were made
Structure of DNA
Discovery of Genetic Code
DNA is Self-Replicating Before Cells divide –Enzymes break bonds between bases –Complementary strands separate –Complementary bases are added to strands –Copy of DNA results
Replication Mechanisms Replication begins at various points Proceeds in both directions
Replication Mechanisms DNA molecule separates at its bases Forms split, or replication fork Each strand acts as a template
Replication Mechanisms Replication proceeds from 5‘ to 3‘ end
Genes One-gene-one-enzyme theory –Production of a given enzyme is under control of a specific gene –Production of a given peptide is under control of a single gene (revised statement)
Gene The unit of heredity Is a sequence of nucleotides Codes for amino acid sequences of polypeptides or for RNA
DNA Sequences Genome = all genetic information Promoters = “start here” part of sequence Introns = extra sequences between polypeptide-specifying portions, are not expressed, interrupt most eukaryotic genes Exons = portions of a gene that are expressed
Repeated Sequences Repetitive DNA 20-50% of eukaryotic DNA May play structural roles in chromosomes
Repeated Sequences Telomeres –At ends of chromosomes –Shorten as cell replicates –Cells do not function when telomeres become too short Telomeres in yellow
Mutations Change can occur in DNA Point mutation or gene mutation –Change in genetic message Chromosome mutation
Sources of Mutation Ionizing radiation Ultraviolet radiation Some chemicals Transposable elements
Transposable Elements “jumping genes” Some DNA sequences move from one position to another Make up more than 40% of human genome First reported by Barbara McClintock
Transposable Elements Significance –Contribute to rate of mutation –May cause visible changes Example: mottling in corn
End Chapter 9