Development of a lethal congenital heart defect in the splotch (Pax3) mutant mouse

doi:10.1016/S0008-6363(97)00172-7

Cardiovascular Research 1997 36(2):163-173; doi:10.1016/S0008-6363(97)00172-7
© 1997 by European Society of Cardiology

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Development of a lethal congenital heart defect in the splotch (Pax3) mutant mouse

Simon J Conway^a^,b^,*, Deborah J Henderson^b, Margaret L Kirby^a, Robert H Anderson^c and Andrew J Copp^b

^aDevelopmental Biology Program, Institute of Molecular Medicine and Genetics, Medical College of Georgia, Augusta, GA 30912-2640, USA
^bNeural Development Unit, Institute of Child Health, University of London, 30 Guilford Street, London WC1N 1EH, UK
^cNational Heart and Lung Institute, Imperial College School of Medicine, University of London, London, UK

^* Corresponding author. Tel.: +1 706 7218775; Fax: +1 706 7218685; E-mail: sconway@mail.mcg.edu

Objective: The splotch (Sp^2H) mutation disrupts the Pax3 geneand is lethal in homozygotes. The aim of the present study wasto investigate the cause of lethality. Methods and results:Using the splotch (Sp^2H) mouse mutant, we demonstrated thatapproximately 60% of Sp^2H homozygotes die in utero at 13.5–14.5days of gestation. All these embryos have cardiac malformationsinvolving partial or complete failure of septation of the outflowtract. Although the cause of death in utero is unknown, thedying embryos are edematous, their superior caval veins areover-expanded, and the fetal liver is enlarged and engorgedwith blood, all signs of cardiac failure. The remaining Sp^2Hhomozygotes die around the time of birth, and these embryoshave grossly normal hearts. All Sp^2H homozygotes have neuraltube defects, either spina bifida, exencephaly, or both. Althoughthese defects clearly do not cause death in utero, they arevery likely responsible for the perinatal death of homozygotesthat survive to late gestation. There is no correlation betweenthe presence or absence of a cardiac defect and the type ofneural tube defect. On the other hand, there is a striking correlationbetween presence of a cardiac defect and reduction or absenceof dorsal root ganglia, which are derivatives of the neuralcrest. Conclusions: In this paper, we show that the lethalityhas a biphasic pattern, and the data strongly suggests thatmid-gestation lethality is due to cardiac defects and not theassociated neural tube defects. This finding supports the ideathat ‘conotruncal’ cardiac defects involving theventricular outflow tracts develop as a result of failure ofthe ‘cardiac’ neural crest to colonise the developingheart in the mid-gestation embryo, and that the resulting heartdefects are solely responsible for the observed mortality.

KEYWORDS Mouse mutant; Congenital heart disease; Neural tube defects; Pax; Splotch; Cardiac neural crest; Heart failure

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