1. Cloning and Stem Cells

2. A wood panel painting depicting the limb transplantation miracle by Saints Cosmas and Damian. According to legend Cosmos and Damian were physicians who successfully transplanted the limb of a dead Ethiopian onto a Turkish patient whose leg required amputation (~C.A. 284).

3. Red Deer replace their antlers every year. It takes ~3 months. We replace our blood cells. ~100 million /hour If part of the human liver is removed, it will re-grow Salamanders and Newts can re-grow their limbs Video – newt limb regeneration Can we regenerate parts of the body? In general: regeneration in vertebrates doesn’t work very well Limbs and most organs aren’t replaced

4. Cells contain DNA DNA makes up discrete recipes or programs called genes Every cell of the body has exactly the same set of genes Depending on the type of cell, some genes are “turned on” and many are “turned off”. Differentiated Cells are those cells with a specialization, and have a very specific set of genes activated. i.e. neurons, liver cells, skin cells, etc. How do cells know what to do, and what not to do?

5. What is a Stem cell? An undifferentiated cell of an embryo that can either Reproduce itself OR Enter a differentiation pathway whereby one of its daughters is differentiated and the other stays an undifferentiated stem cell (totipotent)

6. The goal is to replace cells damaged or destroyed by disease with healthy functioning ones. Some of the diseases they can help include: Cancer Parkinson's disease Diabetes Various injuries (e.g. spinal cord) Eye diseases What are we trying to do with Stem Cells? Types of Stem Cell Therapy Adult stem cell transplants using bone marrow stem cells Adult stem cell transplants using peripheral stem cells Stem cell transplants using umbilical cord blood Therapeutic cloning

7. Can cells be reprogrammed? Experimental Example: Amphibian tadpole: Preprogrammed Muscle cells were transplanted into gut region of cells in the embryo but they stayed as muscle cells. Cells are programmed and “know’ what they will become if the cells stay intact. How?

8. Totipotent: Having the ability to differentiate into ALL cell types. For example, the zygote (newly fertilized egg) and early embryonic cells are totipotent since they can differentiate into any cell type during development. Pluripotent: Having the ability to differentiate into many cell types. In Mammals, embryonic stem cells are pluripotent, and came from totipotent cells. They can differentiate into various fetal or adult cells.

9. Where do we get stem cells?

10. A reliable stem cell reference: http://www.isscr.org/science/faq.htmhttp://www.isscr.org/science/faq.htm Stem cells can be found naturally in 1) A Fertilized Egg (embryonic stem cells (ES)): Video: (human emb. development) 150 cells called (blastocyst) contains two types of cells: 1) trophoblast2) inner cell mass Embryonic stem cells are obtained from the inner cell mass.

11. 2.Cancers can form a variety of cell types (connective tissue, cartilage, blood cells) can be transplanted into host animals and in some cases turn into non-cancerous normal cells 3. (Since 1981) Start w/ an embryo. Blastocyst cells can be put in culture and grow indefinitely. When put into a host they will differentiate into a variety of cells. Other ways to get stem cells: Ovarian cancer stem cells

12. Stem cells are found in small numbers in various tissues in the fetal and adult body Examples: blood stem cells are found in bone marrow → give rise to all specialized blood cell types. newborn baby: umbilical cord, possibly baby teeth and amniotic fluid These adult stem cells are multipotent – able to differentiate into a limited number of cell types.

13. Stem cells tend to make a heterogeneous collection of differentiated cells Video: creating lines We haven’t figured out how to make stems cells differentiate into every single type of tissue. …..Yet.

14. Advantages of Embryonic Stem cells Capacity for indefinite proliferation in culture Can be differentiated into a variety of cells including germ cells Can be maintained as frozen stocks Problems: –Undergo spontaneous genetic changes –Hard to make into certain cell types (e.g. pancreas) (nerve tissue is fairly easy to make, however) –Immuno-rejection unless patient is immuno-suppressed. (not ideal).

15. Nuclear reprogramming and Therapeutic cloning Can we make rejuvenated embryonic cells from adult differentiated cells (of the same individual)? This would avoid the problem of immuno- rejection

16. Somatic Cell Nuclear transfer 1.Start with egg (frog, mouse, human) 2.Use UV to kill pronucleus (egg chromosome)-left w/ cytoplasm 3.Pick up another cell in a way such that the cell wall is broken but intact nucleus (using a special micropipette) 4.Inject the intact nucleus into the cytoplasm-only egg cell. The cell thinks It’s been fertilized. It starts to grow into an embryo and then an adult. http://www.dnalc.org/cloning.html This cloning is inappropriate in humans (called reproductive cloning) video: SCNTvideo: SCNT

17. Problems w/ SCNT (somatic cell nuclear transfer) Some transplanted nuclei show a long- term memory of their original gene state so they won’t allow reprogramming. only about 1/3 of nuclear transplants work However, we’re making progress!

18. Legal Issues In the United States, as of July 2011: it is illegal to use federal funding for research on human embryos derived from SCNT. It is legal to use federal funding for research on embryos derived from IVF, if those embryos are not going to be used for anything else (like making a baby).

19. Long-term Goal Reprogram cells without having them go through a nuclear transfer to an egg

20. Sept. 2007 “Researchers Isolate Adult Stem Cells for First Time in Tendon tissue” (adult fibroblasts) Maybe a cure for Alzheimer's disease, Parkinson's disease, and spinal cord injury, In the news: Lots of stories out there….

21. Induced Plueripotent Stem cells (iPS) also called Adult Stem cells iPS cells from adult human cells Developed by two independent research teams: James Thomson and colleagues at University of Wisconsin-Madison Shinya Yamanaka and colleagues at Kyoto University, Japan

22. Common Ethical Objections Slippery slope – where do you draw the line between frogs & mice, and humans Cloning is unnatural. (Antibiotics are unnatural also) Killing of a potential life. “An embryo = a human being” Actually, an embryo would never progress until it is put into a womb. It’s good for us to see how others tolerate suffering.