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Genetic and Molecular Control of Vertebrate Limb Development and Morphological Diversity

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Genetic and Molecular Control of Vertebrate Limb Development and Morphological Diversity Genetic and Molecular Control of Vertebrate Limb Development and Morphological Diversity Lee Niswander HHMI/ U Colorado Health Sciences Center [email protected] Limb Development Chick Pro: experimental embryology, rapid functional analysis Con: relative lack of genetics Mouse Pro: genetics, genetic manipulation Con: in utero development Bat Pro: evo-devo studies, experimental embryology Con: relative lack of genetics relatively difficult to obtain Diversity of Diversity of Vertebrate Limbs Vertebrate Limbs A s= stylopod s Pr D z= zeugopod z a a= autopod P Modified from: Ridley M. Evolution, 2nd ed. A-P= Anterior-Posterior Blackwell Science 1996 Pr-D= Proximal-Distal P. Martin Int. J. Dev. Biol 1990 The thickened ectoderm at the distal rim of the limb bud is termed the apical ectodermal ridge. Laying down of the cartilage condensations E11.5 Martin, 1990 E12.5 Khokha et al. 2003 s z a Specification Elaboration of Patterning s z a 3 QuickTime™ and a 4 TIFF (LZW) decompressor 2 3 4 are needed to see this picture. 2 5 5 a z ssor ? ture. s pg pg S Z A Plzf/Gli3 dKO Barna et al. Fgf4/Fgf8 dKO Hoxa11/d11 dKO Sun et al. Nature (2002) Davis et al. Nature (1995) 1 Maria Barna AC D H Sin3A N-CoR/ SMRT POZ Zn+ Zn+ Zn+ Zn+ Zn+ Zn+ Zn+ Zn+ Zn+ PLZF (also known as ZFP 145) PLZF translocated to the Retinoic Acid Receptor Alpha (RARα)gene is associated with acute promyelocytic leukemia (APL) PLZF is a sequence specific DNA binding transcriptional repressor belonging to the POK (POZ and Kruppel) family of proteins that can remodel chromatin to a heterochromatic state. Genetic interaction between the transcription factors Plzf and Gli3 s= stylopod s z= zeugopod P D a= autopod z a WT Plzf-/-/Gli3-/- Skeletal elements of the limb are independently regulated s= stylopod s z= zeugopod a= autopod z a WT Plzf-/-/Gli3-/- WT Plzf-/-/Gli3-/- Proximal Distal WT Plzf-/-/Gli3-/- Sox9:the earliest known marker of cartilage differentiation S Plzf and Gli3 are required for the survival of a small population of proximal mesenchyme Tunel E10.5 WT dKO H3-Mitotic Cells E10.5 The dying cells in the Plzf-/-/Gli3-/- limb are marked by BmprIB expression WT Gli3-/-/Plzf-/- Tunel E10.5 BmprIB E10.5 The molecular basis for Plzf-/-/Gli3-/- proximal limb defects Tunel Sox9 WT Plzf-/-/Gli3-/- WT Plzf-/-/Gli3-/- BMPR1B Meis1 WT Plzf-/-/Gli3-/- WT Plzf-/-/Gli3-/- Plzf & Gli3 = Proximal = Mesenchyme = Distal Progenitors Progenitors Specification Elaboration of Patterning s z a 4 3 2 3 4 2 5 5 z ? s pg pg Plzf/Gli3 dKO Barna et al. Comparative evo-devo Mus Carollia from Cretekos, et al., (2001). The evolution of bat morphology Early fossil bat Modern bat (50 million years old) Bat metacarpals have remained constant in length for the past fifty million years Extinct bats z Extant bats • Extinct bats: Icaronycteris, Hipposideros, Archaeonycteris, Palaeochiropteryx • Extant bats: representatives of every modern family Carollia perspicillata • Common name: Seba’s short-tailed bat • Abundance: Very Common • Gestation: 115-120 days • Reproduction: Bi- annually (June to Aug. and Feb. to May) give birth to 1 offspring • Diet: Fruit, pollen, insects • Location: Central and South America Hypothesis: The elongation of bat digits resulted from changes in the temporal and/or spatial expression of a few key regulators of limb development. Day 50 Bat Embryo* (comparable to Day 13 mouse) Early bat digits are similar in size to those of other mammals Day 48 Bat Embryo Day 48 Human Embryo (comparable to Day 12 mouse) (comparable to Day 13.5 mouse) Growth plate morphology: The relative rate of cartilage proliferation and differentiation controls digit length Resting chondrocytes Proliferating Prehypertrophic Hypertrophic *adapted from Weatherbee and Niswander (in press) Hypertrophic zone greatly enlarged in bat Resting Proliferative Pre- Hypertrophic Ossification hypertrophic Zone* Zone Paraffin embedded, sectioned and stained with hematoxylin and eosin Hypertrophic zone greatly enlarged in bat Mouse Bats 100% 90% 80% Zones 70% Ossification 60% % of Hypertrophic metacarpal 50% Maturative 40% Proliferative 30% Resting 20% 10% 0% 17 60 65 70 75 80 85 90 Days Post-Coitum (17 = mouse, all others bat) Application of BMP protein to mouse and rat limbs results in a bat-like morphology (De Luca, et. al., 2001) Wild Type Low BMP High BMP Noggin Can BMP stimulate digit elongation in bats? Bat metacarpals were cultured in either Bmp or Noggin (a BMP antagonist) proteins, or control media BMP Left Limb Right Limb or Noggin Let grow for four days Digit length can be changed by application of either Bmp or Noggin protein Pre-Bmp culture* Post-Bmp culture* *images shown at same scale Digit length can be changed by application of either Bmp or Noggin protein .7 Bmp Ç Length Noggin È Length .6 .5 Difference between post- .4 and pre-culture .3 length of the metacarpal of .2 the 4th digit .1 0 -.1 BMP BMP Noggin Noggin (n=10) Control (n=12) Control (n=10) (n=12) • Differences between Bmp & Bmp Control and Noggin & Noggin Control are statistically significant (p-values = 0.003 and 0.015, respectively) Relative size of the hypertrophic zone can be changed by application of either Bmp or Noggin BMP Hypertrophic Zone Control Relative size of the hypertrophic zone can be changed by application of either Bmp or Noggin protein .45 Bmp Ç HZ % Noggin È HZ % .4 .35 % of 4th .3 metacarpal .25 growth plate composed of .2 hypertrophic .15 zone .1 .05 0 BMP BMP Noggin Noggin (n=7) Control (n=7) Control (n=7) (n=7) • Differences between Bmp & Bmp Control and Noggin & Noggin Control are statistically significant (p-values = 0.028 and 0.046, respectively) Did a change in Bmp expression stimulate digit elongation? Mouse Perichondrium RRPHPH PH P Perichondrium Bat Perichondrium RRPHPH PH P Perichondrium BMP2 BMP4 Both Conclusion BMPBMP Chicken Embryo In ovo surgical and molecular experiments stage 20 chick embryo BMP signaling is required for interdigital cell death Molecular manipulation in the chick embryo * Block BMP signaling - inhibit cell death * Activate BMP signaling - premature cell death Zou and Niswander 1996, Science 272, 738-741 Pizette et al. 1999, Development 126, 883-894 Bat Wing Development How is the webbing between the digits maintained in bat wings? Scott Weatherbee Bat Molecular Evolution Scott Weatherbee Karen Sears MD Anderson Cancer Center Richard Behringer Chris Cretekos SUNY Downstate John Rasweiler BMP signaling occurs in the bat interdigits Forelimb Hindlimb webbing retained webbing removed Similar levels of BMP target (anti-Msx1/2 antibody) in forelimb and hindlimb Fgf8 is expressed in bat interdigital tissue scale bars = 0.5mm Webbing is retained by attenuation of BMP signaling and acquisition of a novel domain of FGF signaling = FGF inhibitor (SU5402) = BMP protein Insert beads Culture for 19-48 hours Analyze for cell death Genome-wide forward genetic screen to directly identify genes required for mouse embryonic development ENU x B6 C3H F1 C3H F1 x G3 G2 wt wt wt “mut” Maria Barna Aimin Liu Limb mutations Tae-Hee Kim Scott Weatherbee control Line 37 Line 11A Line V8 (flexo) Line 20 Line 33D Cardiac L-R patterning Syndactyly Eye Midbrain defect Exencephaly Neural Lung fusion Digit loss and fusion control Line 10 D-V digit duplications Exencephaly Kidney small/missing Lack of eyes Neonatal lethality Lines 99K1/43B “ There is no thought without an image” -Aristotle QuickTime™ and a TIFF (LZW) decompressor are needed to see this picture. From: (Pizette,S & Niswander, L Dev. Bio. 219, 237–249(2000)) Functional Evidence for Early Specification QuickTime™ and a decompressor are needed to see this picture. QuickTime™ and a TIFF (LZW) decompressor are needed to see this picture. 3 4 2 3 4 5 5 Specification Gdf5 Expression z ? s pg s pg z WT Plzf -/-Gli3-/-/ a.
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