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Molecular Genetics of Muscle Disorders Chapter 13 (pp. 369-376)

Molecular Genetics of Muscle Disorders Chapter 13 (pp. 369-376). 650 different Muscles !. Skeletal Muscle For locomotion (voluntary) Cardiac Muscle Heart muscles (involuntary) Smooth Muscle Lining the wall of interior organs (involuntary). 650 different Muscles !.

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Molecular Genetics of Muscle Disorders Chapter 13 (pp. 369-376)

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  1. Molecular Genetics of Muscle Disorders Chapter 13 (pp. 369-376) 650 different Muscles !

  2. Skeletal Muscle • For locomotion (voluntary) • Cardiac Muscle • Heart muscles (involuntary) • Smooth Muscle • Lining the wall of interior organs • (involuntary) 650 different Muscles !

  3. More than 1000 genes required for • proper muscle formation and functioning: • Providing energy to the cell (respiration) • Structure of muscles • Involved in contraction process Muscular Dystrophy Mutations have been found in all of these categories

  4. Muscle Cells: • Can be very long (12 inches) • Multinucleate Figure 13.1

  5. Many nuclei per cell because The cell is soooo long! One nucleus per cell One nucleus per cell

  6. Calcium enters the cell after receiving a nerve impulse to do so, and leaves the cell during the ‘relaxation stage’.

  7. Thick Myofilaments Thin Myofilaments

  8. Mitochondria

  9. Non-covalent interactions Signaling system Figure 13.3

  10. Extracellular Matrix (collagen, etc.)

  11. All linked to a Nucleus

  12. A lot of good, easy-to-understand information is at this < hyperlink

  13. Four Domains

  14. Four Domains Binds to Actin (240 amino acids)

  15. Four Domains Central rod 24 repeats of ≈125 amino acids = 3000 a.a. Binds to Syntrophins, Dystrobrevin, etc. (420 amino acids) Binds to Actin (240 amino acids)

  16. Four Domains Binds to Dystroglycan (280 amino acids) Central rod 24 repeats of ≈125 amino acids = 3000 a.a. Binds to Actin (240 amino acids)

  17. Four Domains Binds to Dystroglycan (280 amino acids) Central rod 24 repeats of ≈125 amino acids = 3000 a.a. Binds to Syntrophins, Dystrobrevin, etc. (420 amino acids) Binds to Actin (240 amino acids)

  18. X-Linked, Recessive • 1 in 3300 male births • Few symptoms until about 5 • 1/3-1/2 have learning disability • First, not able to “keep up” • with other children • Then will start to “waddle” • Then starts to walk on toes • Curvature of spine • Then uses hands to hold self up • Wheelchair only by 10 years • Chest muscles weaken, making • breathing difficult • Respiratory failure (death) at 17 Duchenne Muscular Dystrophy Heart & Lung muscles weaken

  19. Muscles of shoulders & pelvis weaken first

  20. Becker Muscular Dystrophy • A milder form of the same disease • (and mutation of the same gene, Dystrophin) • 1 in 30,000 males • Affected males live longer

  21. Dystrophin Largest gene found in nature = 2.4 million bases 79 Exons

  22. Dystrophin Largest gene found in nature = 2.4 million bases 79 Exons Duchenne Muscular Dystrophy is generally caused by frameshift (or missense mutations) at the 3rd or 4th domains Causing a truncated protein Becker Muscular Dystrophy is generally caused by internal parts of the proteing being missing cDNA cloned in 1987

  23. How would you go about cloning this gene?

  24. Dystrophin 2/3 of cases are inherited, 1/3 are sporadic (new mutations) Second human gene cloned by “Positional Cloning” (the third was Cystic Fibrosis gene) Lots of different labs were looking for this gene, and they took different approaches

  25. 1987 Biopsy of normal and DMD muscle And did gel electrophoresis of the proteins

  26. 1987 Biopsy of normal and DMD muscle And did gel electrophoresis of the proteins Observed a lack of large MW proteins in DMD muscles

  27. Immunoblots “Western Blots”

  28. Normal DMD

  29. Cytogenetic analysis of one DMD patient showed a thinner chromosome band here.

  30. Made Hamster Somatic Cell Hybrids with that guy’s Chromosome X

  31. Made Hamster Somatic Cell Hybrids with this guy’s Chromosome X And probed with 20 random pieces of DNA from a genomic library of Chromosome X (from a healthy person). ….19 probes hybridized, 1 didn’t !

  32. Example of a DMD RFLP Digested with XmnI Koenig, et al., 1987 Cell, Vol. 50: 509.

  33. As they got closer to figuring out that the DMD gene was in the middle of the short arm of the X chromosome they used various fragments of the Genomic Library to screen a cDNA Library. The cDNA Library was made from fetal muscle tissue (female).

  34. A good candidate for a cDNA for DMD would be something large !

  35. 1987 Reported that the most common difference between the healthy DMD gene and the mutated one was a 2000 bp deletion….it was present in about half of 104 boys with the disease.

  36. 1988

  37. Four Domains Binds to Dystroglycan (280 amino acids) Central rod 24 repeats of ≈125 amino acids = 3000 a.a. Binds to Syntrophins, Dystrobrevin, etc. (420 amino acids) Binds to Actin (240 amino acids)

  38. 76 exons Was initially mysterious because the smaller delection was associated With the more-severe form of MD.

  39. http://www.bms.ed.ac.uk/research/others/smaciver/MD%20cause.htmhttp://www.bms.ed.ac.uk/research/others/smaciver/MD%20cause.htm

  40. The role of muscle biopsy in analysis of the dystrophin gene in Duchenne muscular dystrophy: experience of a national referral centre.Tuffery-Giraud S, Saquet C, Chambert S, Echenne B, Marie Cuisset J, Rivier F, Cossee M, Philippe C, Monnier N, Bieth E, Recan D, Antoinette Voelckel M, Perelman S, Lambert JC, Malcolm S, Claustres M.Laboratoire de Genetique Moleculaire et Chromosomique, Institut Universitaire de Recherche Clinique (IURC), CHU de Montpellier, 641 avenue du Doyen G. Giraud, 34093 Montpellier Cedex 5, France. tuffery@igh.cnrs.fr At the DNA level: (89 cases) Substitution = 57% Deletion = 32% Duplication = 9% Insertion =2% At Protein Level: Frameshift = 55% Nonsense = 39% Deletion = 6% * Our textbook says 65% deletions

  41. 79 Exons in all 2003

  42. Healthy muscles DMD muscles Cytochemical staining for Dystrophin makes diagnosis fast * Remember this protein is fairly near the cell surface http://www.neuro.wustl.edu/neuromuscular/pathol/dmdpath.htm

  43. What can be done with boys with DMD? • At early stages • Physical Therapy • Splints, Crutches, Wheelchairs • Surgery • At later stages • Cardiological medicines • Assisted breathing devices (later stages) • Prednisone, a corticosteroid, similar to a hormone • produced by the adrenal glands. Lots of side effects: • weight gain, bone brittleness, cataracts, mood changes… • …more aggressive)

  44. Used adenoviral vector

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