Dominant human genetic diseases that impair reproductive fitness and have high locus heterogeneity constitute a problem for gene discovery because the usual criterion of finding more mutations in specific genes than expected by chance may require extremely large populations. Heterotaxy (Htx), a congenital heart disease resulting from abnormalities in left-right (LR) body patterning, has features suggesting that many cases fall into this category. In this setting, appropriate model systems may provide a means to support implication of specific genes. By high-resolution genotyping of 262 Htx subjects and 991 controls, we identify a twofold excess of subjects with rare genic copy number variations in Htx (14.5% vs. 7.4%, P = 1.5 × 10
−4). Although 7 of 45 Htx copy number variations were large chromosomal abnormalities, 38 smaller copy number variations altered a total of 61 genes, 22 of which had Xenopus orthologs. In situ hybridization identified 7 of these 22 genes with expression in the ciliated LR organizer (gastrocoel roof plate), a marked enrichment compared with 40 of 845 previously studied genes (sevenfold enrichment, P < 10
−6). Morpholino knockdown in Xenopus of Htx candidates demonstrated that five (NEK2, ROCK2, TGFBR2, GALNT11, and NUP188) strongly disrupted both morphological LR development and expression of pitx2, a molecular marker of LR patterning. These effects were specific, because 0 of 13 control genes from rare Htx or control copy number variations produced significant LR abnormalities (P = 0.001). These findings identify genes not previously implicated in LR patterning.cardiac development | Xenopus tropicalis | embryo C ongenital heart disease (CHD) is the most common major birth defect, affecting ∼1% of live births, yet the cause of these lesions remains elusive. Although there is extensive evidence from epidemiologic, twin, and animal model studies supporting strong genetic contributions to CHD, only a small fraction of disease risk has been explained at the molecular level (1). Heterotaxy (Htx) is a severe form of CHD (2), in which normal left-right (LR) asymmetry is not properly established, leading to malformation of any organ that is asymmetric along the LR axis (Fig. 1). During embryonic development, cardiac precursor cells form a symmetric heart tube that undergoes rightward looping to form the geometric framework for the normal four-chambered heart. Defects in looping result in a spectrum of complex CHD in ∼90% of Htx patients (3). CHD associated with Htx still has relatively poor survival, despite surgical management.Studies in model systems have established a remarkably wellconserved genetic program governing patterning of the vertebrate LR axis (4-6) and cardiac development. LR asymmetry is established during gastrulation at the node (LR organizer) via dynein-driven, directional beating of cilia. Cilia beating results in leftward flow of extraembryonic fluid (nodal flow), which induces nodal signaling and Pitx2 expression in the left lateral-plate mesoderm (7,8). Abnormal LR develo...
