1 / 24

Honors Genetics Ms. Gaynor

Chapter 1 Introduction to Genetics. Honors Genetics Ms. Gaynor. What is Genetics?. the study of how genes act to produce the characteristics of a living organism. This course will be divided into 3 areas of study: classical genetics how traits are inherited molecular genetics

zarek
Télécharger la présentation

Honors Genetics Ms. Gaynor

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Chapter 1 Introduction to Genetics Honors Genetics Ms. Gaynor

  2. What is Genetics? • the study of how genes act to produce the characteristics of a living organism. • This course will be divided into 3 areas of study: • classical genetics • how traits are inherited • molecular genetics • how DNA encodes traits • genomics • how all an organism's genes function and interact.

  3. What will we study in Genetics? • DNA and its function! • We’ll mostly talk about eukaryotic cells (like yours) but we will also talk about prokaryotic (bacterial) molecular genetics. • Topics will include • DNA (gene) interactions • Chromosomal inheritance • Biotechnology • Mutations • Population genetics (evolution and DNA)

  4. Did you know? • Scientist named Mendel 1st started studying genetics in 1800’s. • BUT…DNA’s structure was discovered in 1953. • Study of heredity called GENETICS evolved QUICKLY from the days of Gregor Mendel (“Father of Genetics”) to DNA in LESS THAN 100 YRS! • Discovery of the DOUBLE HELIX launched the era of Molecular Genetics & Biotechnology

  5. What came next in 1980’s? • BIOTECHNOLOGY • use of living organisms (Ex: bacteria or yeast) or their products to modify human health and the human environment. I LOVE GENETICS!

  6. What came next in 1980’s? • Biotechnology • Manipulating DNA • Allows us to clone cells/ whole animals • Turn genes “on” and “off” • Biotechnology is continually expanding…. I’m called Copy Cat. What’s Your Name?

  7. Why is Biotechnology (Genetic Engineering) Important? • Biotechnology has been used for • Paternal/Maternal testing and Gene therapy • Forensic science/Criminology • Genetic modification of animal/animal products • Genetic modification of crop plants for: • Increased insect & viral resistance • nutritional enhancement (new traits)

  8. 1st Genetically Modified Animal to be Sold as a Pet • GloFish (2003)

  9. Biotechnology and Genes • Gene therapy and genetic testing are important parts of medicine. • Inserting genes in DNA • Turning genes “on” and “off” WE ARE GLOWING!!!

  10. Biotechnology has 4 Applications in Major Industrial Areas • health care (medical) • Ex: hormone (insulin) production, genetic testing, cloning • crop production and agriculture • Ex: GM foods, beer/milk products • non food (industrial) uses of crops and other products • Ex: Biodegradable plastics and biofuels • Environmental uses • Ex: bioconversion of waste using genetically altered bacteria in cleanup of oil spills

  11. Table 1.1

  12. HUMAN GENOME PROJECT (announced in 2000…completed in 2003) Figure 1.17

  13. Genomics, Proteomics, and Bioinformatics are New and Expanding Fields • Genomics • studies genome (DNA) sequences • Proteomics (DNA mRNA  protein) • studies protein (amino acid) sequences that lead to traits and characteristics • All life has a common origin, and genes with similar functions in different organisms are similar in structure and DNA sequence.

  14. How do scientists study Genetics? • Use MODEL ORGANISMS • An organism whose genetic material has been altered by genetic engineering techniques • Model organisms for genetic study meet certain criteria: • easy to grow • short life cycle • produce many offspring • relatively inexpensive • easy to manipulate/mutate • “KNOCK OUT” or “TURN OFF” genes then look for consequences

  15. What are some common MODEL organisms? • E. Coli bacteria • Yeast • Nematode (round) worms called C. Elegans • Fruit Fly called Drosophila melanogaster • Common Mouse

  16. Why not use HUMANS? • Too big • 100 trillion cells (excluding RBC’s) • 5-6 feet tall • ~40,000 genes on 46 chromosomes • 6 FEET of DNA • Lifespan is long (40-75 years on average) • New generation ~every 25 years • Hard to mutate! Wait…it’s not ethical either! • HUMANS ARE NOT AN EXPERIMENTAL ORGANISM 

  17. E. Coli bacteria (prokaryote) • Commonly found in human digestive system • 4288 genes on 1 chromosome • Rapid growth • E. coli cells can double in number after only 20 minutes. • Simple food needs • VERY easy to manipulate its DNA • Making recombinant DNA using plasmids • Taught us about: • Viral diseases and reproduction

  18. Yeast (unicellular, eukaryote) • Very small and easy to find • 4000 line up to make 1 inch! • Reproduces easily every 90 minutes • 6000 genes on 6 chromosomes • 31% are equivalent to human genes • Its ENTIRE genome of DNA was completely sequenced in 1996. • Originally taught us about: • Human reproduction and cancer

  19. C. Elegans (Round worm) (multicellular, eukaryote) • Very small • 1 mm long! • Hermaphrodites (male & female parts) • Life span: 2-3 weeks • New offspring EVERY 3 days • 19,099 genes • 40% are equivalent to human genes • Taught us about: • Cell suicide (apoptosis) and cell health, animal development

  20. Fruit Fly called Drosophila melanogaster (multicellular, eukaryote) • Small • 4 mm long! • Life span: 2-3 months • New offspring EVERY 10 days • 13,600 genes • 50% are equivalent to human genes • Its ENTIRE genome of DNA was completely sequenced in 2000. • Lots of mutations to study! • Taught us about: • Animal development, neurons, behavior, cancer

  21. Common Mouse(multicellular, eukaryote) • CLOSEST relative to human among the “MODELS” • Vertebrates & mammals like humans • Life span: 2 years • New offspring EVERY 9 weeks • ~40,000 genes (same as humans) • ~99% are equivalent to human genes • Taught us about: • Human disease, emotions, memory, reproduction

  22. Human Disease Genes ALSO Found in Model Organisms • Flies, worms, and yeast share genes with humans for DISEASE, such as: • Cardiac Disease • Deafness • Pancreatic Cancer (flies only) • Duchenne Muscular Dystrophy (NOT yeast) • Skin Cancer • Wilson’s Disease • Colon Cancer • Leukemia (NOT yeast) • Cystic Fibrosis (NOT yeast)

  23. And now…America’s Next Top “Model”? • Zebrafish! • Vertebrate (like mice) • Closer to humans than fruit flies or worms • These fish lay 100’s of translucent eggs OUTSIDE the female’s body • Can see developmental mutations easily! That fish sure can “SMEYES”

  24. We Live in the Age of Genetics • Genetics is the core of biology. • Helps to understand the functions and malfunctions of a biological system. Next up…the study of different cell types!

More Related