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“Bio-Engineering” in Livestock How do these “tools” fit into modern livestock production?

+. =. “Bio-Engineering” in Livestock How do these “tools” fit into modern livestock production?. Chad J. Mueller, PhD Dept. of Animal Sciences. Is this “Pandora’s Box”, and why did we open it?. Cheap food = lower market prices!! Not expenses!!

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“Bio-Engineering” in Livestock How do these “tools” fit into modern livestock production?

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  1. + = “Bio-Engineering” in LivestockHow do these “tools” fit into modern livestock production? Chad J. Mueller, PhD Dept. of Animal Sciences

  2. Is this “Pandora’s Box”, and why did we open it? • Cheap food = lower market prices!! • Not expenses!! • Growing populations = less tillable acres + greater regulations • Less producers & higher labor costs

  3. What are these “Bio-engineering” tools? • Metabolic modifiers • Transgenics • Cloning

  4. “Bio-engineering” tool:Metabolic Modifiers

  5. Metabolic modifiers • Compounds that modify animal metabolism in specific and directed ways. • Improve gain and lactation efficiencies, reduce waste output • Two main classes • Somatotropins (STs) • -adrenergic agonists

  6. Metabolic modifiers: Somatotropins • Use of recombinant DNA technologies • Specie-specific proteins (pituitary gland) • Dairy (bovine ST) & swine (porcine ST) industries • bST: • Commercial sales began in 1994 • Posilac™ • Used in approx. ½ U.S. dairy herds • Used in 19 countries •  milk production (8 – 10 lb./hd/d), lactation efficiency (milk / feed)

  7. Metabolic modifiers: Somatotropins • pST: • Improved nutrient use for lean tissue production • Less fat! • Improved carcass value • Less dietary protein required • Reduced N waste per unit of feed (pollution) • Currently being tested by FDA • Commercial use by 14 countries (Etherton et al., 2003)

  8. Metabolic modifiers: -adrenergic agonists • Known as: • Phenethanolamines • Repartitioning agents • Similar in structure to catacholamines • Dopamine, norepinephrine, epinephrine • Use same cell receptors ( or -receptors) • Stimulate protein anabolism, reduce protein turnover and lipogenesis •  lean tissue,  % carcass fat

  9. Metabolic modifiers: -adrenergic agonists • U.S. = Ractopamine • 2 commercial products • Paylean 9™ for swine • Optaflexx 45™ for beef cattle

  10. “Bio-engineering” tool:Transgenics

  11. Transgenics Two common methods: • Injection of DNA into pronucleus of fertilized ovum • Targeted insertion of DNA through embryonic stem cells Transgenic animals carry and express genetic information not normally found in that host or species

  12. Transgenics • 1981: First transgenic mouse • Insertion of hGH into a mouse (Singleton, 1999) • Production of monoclonal antibodies & anti-inflammatory agents

  13. Transgenics • Why use transgenics? • Study gene function and regulation • Genome mapping • Model development and progression of human diseases • Cystic fibrosis • Multiple sclerosis • Xenotransplantation • Disruption of Gal1-3Gal enzyme • Disrupt human viral diseases • Hepatitis & liver transplants CAST, 2003

  14. Transgenics • Benefits of transgenics in animal production? • Phytase enzyme in swine / poultry • Improved gain efficiency and protein production • Super-salmon • Antifreeze protein in flounder + Chinook salmon • Reduced-lactose milk • Human therapeutic proteins • Antithrombin III, lactoferrin, monoclonal & polyclonal antibodies, serum albumin PEW Initiative, 2005 FDA, 2005

  15. Transgenics • Functional genomics must be understood • Single-gene traits vs multiple-gene traits • Is there a marketable impact? • Economically & sociably • “Input” traits vs “Output” traits Bremel et al., 2001

  16. “Bio-engineering” tool:Cloning

  17. Cloning • The production of genetically-identical animals by nuclear transfer from somatic cells to unfertilized eggs. Tian et al., 2003. (Reprod. Biol. and Endo.)

  18. Cloning • Cloning through the ages: • 1952: Cloning via nuclear transfer (frog) • 1989-1990: First mammals cloned • 1995: First cloning via cultured mammalian cells • 1997: First cloning via adult cells – DOLLY • First cloning via transgenic adult cells – POLLY • 1998 – 2000: Cloning of cattle, pigs, mice, goats and monkeys using adult cells • 2001: First reported cloned human embryo • 2002: First cloned pet

  19. Cloning • Applications: • Reproduce superior traits • Growth, milk production, etc. • Especially in conjunction with transgenics • Facilitate “pharm” animal production • Human therapeutic proteins • Xenotransplantation • Bio-terrorism defenses •  production of antibodies to botulinum toxin in milk

  20. Cloning • Applications: • Recover “lost” or “endangered” species • Pets?

  21. Cloning • Very expensive • Technology needs continued refinement • Nuclear transfer is successful <1% of the time • High rates of pregnancy loss and neonatal death • Developmental abnormalities • Incomplete reprogramming of genome • Incomplete epigenetic reprogramming

  22. “Bio-engineering” tools:Ethical Considerations Benefits vs Risks

  23. Ethical Considerations • “When faced with serious illness, most people are willing to take risks to combat a disease. Food is different…since it is so basic, both physically and emotionally. It's not surprising that consumers are extremely averse to any food-related risk, especially if the risk is perceived as imposed by someone else, beyond individual control and without any countervailing benefit. Consumers…are concerned mostly about such potential health problems as allergic reactions and antibiotic resistance.” Carol Tucker Foreman, Director of the Food Policy Institute at the Consumer Federation of America (CFA) in Washington, D.C.

  24. Ethical Considerations • Metabolic modifiers: • Health risks to humans? • Effect on human growth? • Allergies? • Should food products be labeled? • Animal welfare • Developmental and health issues • Mastitis, heart palpitations, conception rates, inflammation of injection sites (bST), arthritis, lameness

  25. Ethical Considerations • Transgenic animals: • Health risks to humans? • Effect on human growth? • Allergies? • FDA says “NO” to consumption • Animal welfare • Developmental problems due to introduced genes • Arthritis, gastric ulcers, high mortality rates, degenerative joint disease • Issue of animals with only partial gene incorporation?

  26. Ethical Considerations • Cloned animals: • Health risks to humans? • FDA says “OK” to consumption • Animal welfare • Poor survivability rates, developmental problems, behavioral abnormalties • Shortened life spans, health problems

  27. Ethical Considerations • Additional clone and transgenic animal issues: • “Accidental” incorporation of animals to wild populations • Limited gene pool? • Impact on the use of certain resources • What information do we lose by “speeding up” the generation interval? • Morally…are we “playing God”?

  28. Legislative regulation • Food and Drug Administration (FDA) • Center for Veterinary Medicine • 2003 – 2004 legislative session • 16 bills on transgenic fish • 13 bills on transgenic plants and animals for “pharma” applications • Public is worried about who is in control • Private enterprises vs government

  29. Questions to Ponder!! • Should farm animals be bio-engineered for food production? • Cloned animals: What traits are superior, and should we value variation? • Who should be “in charge” of this technology, or ultimately who is responsible for this technology (and it’s consequences)? • Should the public consider “food production” and “Pharm production” as separate issues?

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