2. A A. Abugabal GEN 301

3.  Acquire the students with  good basic grounding in the molecular structure, organization and function of genetic material  To distiguish between different types of molecular markers  To critically appraise the different methods used in molecular mapping  To study the application of genetic analysis in different organisms

4. Methods of AssessmentWeighting % Project Quizzes Assignments Mid-Term Lab Work Final Exam: 7% 3% 5% 20% 25% 40% Assessment Details:

5.  The history of genetics is quite extensive.  It has taken the work of many brilliant scientists to finally conceive the structure of the DNA molecule or to even conceive it as the hereditary material life.  In this opening genetics section it is important to understand scientists' achievements.  Appreciate and understand their method, do not get caught up in history and dates.

7.  Gregor Mendel: mid 1800’s

8. 1865 Gregor Mendel  By studying pea plants,  discover the basic rules of heredity of garden pea.  Characteristics are inherited in discrete units (later called genes)  An individual organism has two alternative heredity units for a given trait (dominant trait vs. recessive trait)

9.  1869 Johann Friedrich Miescher discovered DNA and named it nuclein. Johann Miescher 1881 Edward Zacharias showed chromosomes are composed of nuclein.

10.  1899 Richard Altmann renamed nuclein to nucleic acid.  By 1900, chemical structures of all 20 amino acids had been identified  1902 - Emil Hermann Fischer wins Nobel prize: showed amino acids are linked and form proteins Emil Fischer

11.  Thomas Hunt Morgan  Worked at Columbia University; later at CalTech  Studied fruit fly eye color, determining that trait was sex-linked  Won the Nobel Prize in 1933 for his work on chromosomes and genetics  1911 – Thomas Hunt Morgan discovers genes on chromosomes are the discrete units of heredity Thomas Morgan

12. early 1900’s Studied fruit fly eye color, determining that trait was sex-linked  1911 – Thomas Hunt Morgan discovers genes on chromosomes are the discrete units of heredity Won the Nobel Prize in 1933 for his work on chromosomes and genetics

13.  By this point, it was known that genetic material was located on a chromosome  This genetic material was in discrete units called genes

14. DNA RNA Protein Components Involve in Molecular Biology By this stage, It was NOT known whether the gene was simply a protein, or whether it was composed of DNA

15.  Since the late 1950s and early 1960s, molecular biologists have learned to  Characterize, isolate, and manipulate the molecular components of cells and organisms, which are: 1. DNA, the storage of genetic information 2. RNA 3. Proteins, the major structural and enzymatic type of molecule in cells.

16.  1930’s  Various experiments identify chromosomes as the source of genetic information  Chromosomes are composed of mainly proteins and deoxyribonucleic acid (DNA)  The DNA molecule was considered too simple to be important so proteins were thought to carry the genetic information

17. The Molecular Basis of Inheritance Evidence that DNA is a genetic material Came from

18. Fred Griffith (1928) – Experiments with pneumonia and bacterial transformation determined that there is a molecule that controls inheritance. Oswald T. Avery (1944) - Transformation experiment determined that DNA was the genetic material responsible for Griffith’s results (not RNA). Erwin Chargaff (1947) – noted that the the amount of A=T and G=C and an overall regularity in the amounts of A,T,C and G within species. Hershey-Chase Experiments (1952) – discovered that DNA from viruses can program bacteria to make new viruses.

19.  Late 1920’s Frederick Griffith from Britain worked with bacteria “Streptococcus pneumoniae”  Defined the term, “TRANSFORMATION”

20.  Their conclusion was based on experimental evidence that only DNA worked in transforming harmless bacteria into pathogenic bacteria

21. Hershey and Chase concluded that the injected DNA of the phage provides the genetic information that makes the infected cells produce new viral DNA and proteins, which assemble into new viruses.

22. Griffith 1928 & Avery 1944: DNA (not RNA) is transforming agent. Hershey-Chase 1953: DNA (not protein) is the genetic material. - RNA (not protein) is genetic material of some viruses, - but no known prokaryotes or eukaryotes use RNA as their genetic material. Alfred Hershey Nobel Prize in Physiology or Medicine 1969 22 Conclusions about these early experiments:

24.  Won Nobel prize in chemistry in 1954 for work in chemical bonding;  Nobel peace prize in 1962 for his campaign against above-ground nuclear testing  He also worked on the structure of DNA, but came up with a TRIPLE HELIX  He thought DNA was 3 strands with the phosphates on the inside

25.  X-ray diffraction studies of Rosalind Franklin & Maurice H. F. Wilkins to study the structure of DNA.  The diffraction pattern can be used to deduce the three-dimensional shape of molecules. Edwin Chargaff  1950 – Edwin Chargaff find Cytosine complements Guanine and Adenine complements Thymine What about? Rosalind Franklin

26.  Their results using X-ray crystallography gave Watson and Crick the necessary information they needed to come up with the double helix structure  Width of the helix  Spacing of the nitrogenous bases  DNA molecule was made up of two strands, forming a double helix

27. 1953 proposed the Double Helix Model based on two sources of information

28. 1.Base composition studies of Erwin Chargaff indicated double-stranded DNA consists of ~50% purines (A,G) and ~50% pyrimidines (T, C) amount of A = amount of T and amount of G = amount of C(Chargraff’s rules) %GC content varies from organism to organism Examples:%A%T%G%C%GC Homo sapiens 31.031.519.118.437.5 Zea mays 25.625.324.524.649.1 Drosophila 27.327.622.522.545.0 Aythya americana 25.825.824.224.248.4 28 Structure of DNA

29. James D. Watson/Francis H. Crick 1953 proposed the Double Helix Model based on two sources of information: 2.X-ray diffraction studies by Rosalind Franklin & Maurice Wilkins Conclusion-DNA is a helical structure with distinctive regularities, 0.34 nm & 3.4 nm. 29 Two sources of information

30. Francis H.Crick Watson, J.D. and F.H. Crick, “Molecular Structure of Nucleic Acids. 1962: Nobel Prize in Physiology and Medicine Conclusion-DNA is a helical structure with distinctive regularities, 0.34 nm & 3.4 nm. James D.Watson

31.  1950s – Mahlon Bush Hoagland first to isolate tRNA  1952 – Alfred Hershey and Martha Chase make genes from DNA Mahlon Hoagland  1941 – George Beadle and Edward Tatum identify that genes make proteins George Beadle Edward Tatum  1956 George Emil Palade showed the site of enzymes manufacturing in the cytoplasm is made on RNA organelles called ribosomes. George Emil Palade

32.  1970 Howard Temin and David Baltimore independently isolate the first restriction enzyme This means that: DNA can be cut into reproducible pieces at specific site by restriction enzymes called endonuclease The pieces can be linked to bacterial vectors and introduced into bacterial hosts.This is called (gene cloning or recombinant DNA technology)

33.  1977 Phillip Sharp and Richard Roberts demonstrated that pre-mRNA is processed by the excision of introns and exons are spliced together. Phillip Sharp Richard Roberts

34.  1986 Leroy Hood: Developed automated sequencing mechanism  1986 Human Genome Initiative announced  1995 Moderate-resolution maps of chromosomes 3, 11, 12, and 22 were published  These maps provide the locations of “markers” on each chromosome to make locating genes easier Leroy Hood

35.  1995 John Craig Venter: First bacterial genomes sequenced  1995 Automated fluorescent sequencing instruments and robotic operations  1996 First eukaryotic genome- yeast-sequenced John Craig Venter

36.  Molecular Biology 1997-1999  1999 First human chromosome (number 22) sequenced  Molecular Biology 2000-2001 2001 International Human Genome Sequencing published the first draft of the sequence of the human human genome

37.  April 2003 Human Genome Project Completed  Mouse genome is sequenced.  April 2004 Rat genome sequenced.  Next-generation sequencing – genomes being sequenced by the dozen

38.  Molecular genetics is the field of biology and genetics that studies the structure and function of genes at a molecular level.biologygeneticsgenesmolecular  Molecular genetics employs the methods of genetics and molecular biology to elucidate molecular function and interactions among genes. It is so called to differentiate it from other sub fields of genetics such as ecological genetics and population genetics.genetics molecular biologyecological genetics population genetics  Molecular genetics helps in understanding developmental biology, genetic mutations that can cause certain types of diseases.developmental biology  Through utilizing the methods of genetics and molecular biology, molecular genetics discovers the reasons why traits are carried on and how and why some may mutate.