The heart is the first organ to form, and its development involves an intricate and complex series of events that must occur in a coordinated spatial and temporal fashion (44, 60, 75). The heart develops from bilaterally symmetric cardiogenic primordia that migrate and fuse at the embryonic midline to form a functional primitive heart tube that subsequently undergoes rightward looping to orient the atrial and ventricular chambers and properly align the outflow tract (OFT). As the chambers mature, the trabecular layer within the ventricles is elaborated, endocardial cushions form and fuse, and the chamber walls grow and thicken as the cardiomyocytes continue to proliferate and differentiate. A critical event in cardiac development related to human congenital heart defects (CHD) is septal morphogenesis, which commences during midgestation. The single ventricle becomes septated by a process involving fusion of the muscular interventricular septum (IVS) with the endocardial cushions, and further septation and valve formation continues until birth to ensure unidirectional flow of blood. Since multiple cell types, including those derived from the myocardium, endocardium, epicardium, and neural crest, contribute to the complex process of valvuloseptal morphogenesis, it is not surprising that CHD associated with aberrant septation of the OFT are quite common. Indeed, CHD afflict nearly 1% of newborn infants each year, and defective valvuloseptal morphogenesis is the leading cause of preterm mortality in the United States (22, 23, 53, 59). Thus, understanding the precise mechanisms underlying cardiac morphogenesis will aid in the identification of new therapies to target a multitude of congenital diseases (48). Both forward and reverse genetic studies with Drosophila melanogaster, zebrafish, Xenopus laevis, and mice have been instrumental in determining the transcription factors required for vertebrate heart specification, patterning, and differentiation (42). Included in this growing list of key cardiac specification/differentiation transcription factors are Nk factors (cardioblast specification), MEF2 and GATA factors (cardiomyocyte differentiation), d- and e-Hand (right and left ventricle formation, respectively), and TBX factors (ventricular septation) (42). In spite of this wealth of information regarding the transcription factors that coordinate cardiac morphogenesis, the signaling mechanisms that regulate heart formation are only just beginning to be elucidated. Of note, fibroblast growth factor (FGF) signaling regulates mesodermal differentiation into cardiac primordia, BMPs (members of the transforming growth factor β2 [TGF-β2] superfamily) regulate cardioblast specification, cushion formation, and OFT septation, and the neuregulin growth factors ErbB2 and ErbB4 are required for the development of trabeculae (44). Genetic evidence indicates that the integrin class of fibronectin-binding adhesion receptors (α5β1 and others) can also regulate both the form and function of the heart (8, 21, 55, 56, 58, 66, 74). Integrin ligation drives the recruitment of a number of structural and signaling molecules to the ventral plasma membrane collectively termed a focal adhesion, which serves to link the force-generating actin cytoskeleton inside the cell to the extracellular matrix (ECM) and to coordinate the activation of downstream signaling pathways (28). The nonreceptor tyrosine kinase focal adhesion kinase (FAK) is strongly activated by both integrins and growth factors and is a likely candidate to integrate downstream signals from these diverse pathways during growth and development (50). FAK is expressed at relatively high levels in the mouse mesoderm at embryonic day 7.5 (E7.5) and continues to be expressed in the heart and several other tissues throughout adulthood (15). Germ line deletion of FAK resulted in mesodermal defects and embryonic lethality between E8.5 and E10. The fak−/− embryos showed a phenotype similar to that observed for both fibronectin- and α5-null mice (30, 74). Although a rudimentary, nonbeating heart was apparent in some of these embryos, serial sectioning through fak−/− hearts revealed a lack of separate mesocardial and endocardial layers, which is indicative of defective cardiomyocyte maturation (15). Interestingly, germ line deletion of the FAK binding partners paxillin and Crk-associated substrate (CAS) also led to embryonic lethality associated with similar cardiac defects (19, 25). Paxillin and CAS are both adapter proteins that upon phosphorylation by FAK recruit additional signaling molecules to the focal adhesion complex and cause subsequent activation of downstream mitogen-activated protein kinase and GTPase-mediated signaling cascades (51). Taken together, these studies indicate that modulation of focal adhesion-dependent signals likely plays an important role in cardiac development and/or function. In order to study the time- and tissue-dependent requirements for FAK in mouse development, Beggs et al. recently generated and characterized a mouse line (fakflox/flox) in which exon 20 of the FAK gene (encoding the ATP binding domain) is flanked by loxP sites (3). We recently used this line to conditionally delete FAK from adult cardiomyocytes by use of a well-characterized mlc2vCre line. Somewhat surprisingly, we found that FAK is dispensable for basal cardiac function and myocyte viability. However, FAK was required for appropriate age- and pressure overload-induced compensatory myocyte hypertrophy. Indeed, mice with myocyte-restricted depletion of FAK had a blunted hypertrophic response that manifested in compromised heart function but not premature death (12). Herein, to determine whether FAK might play a direct role in cardiac morphogenesis, we generated a mouse with embryonic FAK deficiency in nkx2-5-expressing cells by use of a recently described Cre knock-in mouse line (46). We found that embryonic deletion of FAK in the nkx2-5-expressing cells results in perinatal lethality associated with a profound subaortic ventricular septal defect (VSD) and an abnormal OFT alignment. FAK inactivation does not affect myocyte growth or survival but regulates myocyte migration, a function that may play a role in the proper fusion of OFT cushion tissue with the muscular IVS.