Transcript CHAPTER 16
Molecular Basis of Inheritance Chapter 16 DNA as Genetic Material • Watson and Crick – 1st scientists to propose structure of DNA responsible for transmission of traits from 1 generation to next. • Requires precise transmission occurs. http://www.ncbe.reading.ac.uk/DNA50/Resources/wc1993.gif • Griffith - injected live bacterial strains into mice. • Mixed R strain of bacteria (harmless) with heat-killed S strain (harmful) and injected it. • After mouse died, removed strain from mouse. • Transformation - change in genotype and phenotype due to assimilation of foreign substance (now DNA) by cell. • Substance found to be DNA supported by injecting bacteria into viruses. • Viruses consist of DNA (sometimes RNA) enclosed by protective coat of protein. http://www.monografias.com/trabajos5/virus/Image164.gif • To replicate - virus infects host cell; takes over cell’s metabolic machinery. • Viruses that specifically attack bacteria - bacteriophages (phages) • Hershey and Chase labeled protein and DNA - injected them into bacteria. http://www.swbic.org/products/clipart/images/bacteriophage.jpg • Hershey and Chase concluded that injected DNA of phage provides genetic information that makes infected cells produce new viral DNA and proteins, which assemble into new viruses. • DNA doubles prior to mitosis. • By 1940’s - discovered that DNA was made of bases. • Adenine, thymine, cytosine, and guanine. • Chargaff’s rules - an even amount of thymine and adenine. (and guanine and cytosine) http://fig.cox.miami.edu/~cmallery/150/gene/BasePairing.gif • Was known that sugar of one nucleotide attached to phosphate of another - forms backbone of DNA. • Watson 1st to figure out that DNA was in helix shape + specific distance between nucleotides. • Partnered with Crick – came up with double stranded model of DNA double helix. Fig. 16.5 Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings • Found that purine has to pair with pyrimidine to achieve distance needed. • Knew that adenine always paired with thymine and cytosine always with guanine. • Discovered that bases were held together by hydrogen bonds. • Adenine forms 2 hydrogen bonds only with thymine; guanine forms 3 hydrogen bonds only with cytosine. • Each gene found to have unique sequence of nitrogen bases - DNA strands not all the same. http://academy.d20.co.edu/kadets/lundberg/dna_wallpaper/dna800x600.jpg DNA Replication and Repair • Watson and Crick discovered each strand of DNA can make template to make more DNA. • Cell copies DNA - each strand forms as template to determine new complementary bases. • Nucleotides pair in complementary fashion, one by one. • Happens by semiconservative replication - each DNA molecule has one parent strand and one daughter strand. • Idea later supported through bacteria studies. • This • Even though process is amazingly quick, only about 1 in a billion nucleotides copied wrong. • Proteins and enzymes also part of process, not just nucleotides. http://www.bio.miami.edu/dana/250/nucleotides.jpg • Origins of replication - where replication process begins. • Bacteria - 1 site - replication looks like bubble moving along DNA. • Eukaryotes - many origins of replication on each chromosome. • Origin sites - DNA strands separate forming replication “bubble” with replication forks at each end. • Elongation of DNA catalyzed by DNA polymerase. • Polymerase adds complementary bases to growing strand of new DNA. • Strands of DNA - antiparallel. • Sugar-phosphate backbones run in opposite directions. • Each end of strand labeled either 5’ end or 3’ end. • Nucleotides only be added to 3’ end. • DNA strand can only elongate from 5’ end to 3’ end. • Replication fork - problem - system because strands run in opposite directions (antiparallel) http://www.mie.utoronto.ca/labs/lcdlab/biopic/fig/11.16.jpg • 1 parent strand (leading strand - one that runs 3’ to 5’) used as template to keep complementary strand continuous. • Other strand (lagging strand - one that runs 5’ to 3’) copied from fork in small segments - Okazaki fragments. http://www.biology.arizona.edu/molecular_bio/problem_sets/nucleic_acids/graphics/repfork1.gif • Fragments “glued” together by DNA ligase to form backbone (made of sugar and phosphate) of single DNA strand. • Polymerase adds nucleotides to strands, cannot start whole process. • Done by a piece of RNA - primer. • Primase links ribonucleotides that are complementary to DNA template into primer. http://www.biologie.uni-hamburg.de/b-online/library/bio201/primase.jpg • Once primer formed, polymerase can add DNA nucleotides to growing daughter strand of DNA. • Later - different DNA polymerase replaces original RNA with new complementary DNA nucleotides there is no RNA left in strand. • Helicase - untwists double helix of DNA at replication fork. • Single-strand binding proteins help keep strands apart from one another during replication. • At replication fork, leading strand copied continuously into fork from single primer. • Lagging strand copied away from fork in short segments, each requiring new primer. • Original errors in reading of template occur. • Enzyme (DNA polymerase) removes mistake and replaces it. • Some things can alter DNA outside of body. http://library.thinkquest.org/C0123260/basic%20knowledge/images/basic%20knowledge/DNA/polymerase%201.jpg • X-rays and UV rays can alter DNA after replication. • Mistakes can be fixed after DNA synthesis because cell continually monitors DNA. • Mismatch repair, special enzymes fix incorrectly paired nucleotides happens in certain types of cancers. http://www.sinauer.com/cooper4e/sample/Figures/Chapter%2006/highres/CELL4e-Fig-06-24-0.jpg • Nucleotide excision repair, nuclease cuts out segment of damaged strand. • Xeroderma pigmentosa (genetic disease) cannot go through process. • Disease prevents person from going in sun because UV rays interfere with DNA replication. • More susceptible to skin cancer because they cannot fix mistakes. http://162.129.70.33/images/xeroderma_pigmentosa_2_040620.jpg • Limitations in DNA polymerase create problems for linear DNA of eukaryotic chromosomes. • Ends of DNA strand can break down from constant replication. Fig. 16.18 Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings • Ends of eukaryotic chromosomal DNA molecules – telomeres special nucleotide sequences. • Telomeres protect genes from being eroded through multiple rounds of DNA replication. • When telomeres shorten, telomerase uses piece of RNA to lengthen telomere. • Telomerase not present in all cells life span to certain tissues or organism itself. • Important for telomerase to be present in gamete cells so they can pass long telomeres on to zygote. • Active telomerase in body cells can be responsible for cancer cells because cells keep dividing.