Jun Maeda

Tbx1 regulates fibroblast growth factors in the anterior heart field through a reinforcing autoregulatory loop involving forkhead transcription factors

Birth defects, which occur in one out of 20 live births, often affect multiple organs that have common developmental origins. Human and mouse studies indicate that haploinsufficiency of the transcription factor TBX1 disrupts pharyngeal arch development, resulting in the cardiac and craniofacial features associated with microdeletion of 22q11 (del22q11), the most frequent human deletion syndrome. Here, we have generated an allelic series of Tbx1 deficiency that reveals a lower critical threshold for Tbx1 activity in the cardiac outflow tract compared with other pharyngeal arch derivatives, including the palatal bones. Mice hypomorphic for Tbx1 failed to activate expression of the forkhead transcription factor Foxa2 in the pharyngeal mesoderm, which contains cardiac outflow precursors derived from the anterior heart field. We identified a Fox-binding site upstream of Tbx1 that interacted with Foxa2 and was necessary for pharyngeal mesoderm expression of Tbx1, revealing an autoregulatory loop that may explain the increased cardiac sensitivity to Tbx1 dose. Downstream of Tbx1, we found a fibroblast growth factor 8 (Fgf8) enhancer that was dependent on Tbx1 in vivo for regulating expression in the cardiac outflow tract, but not in pharyngeal arches. Consistent with its role in regulating cardiac outflow tract cells Tbx1 gain of function resulted in expansion of the cardiac outflow tract segment derived from the anterior heart field as marked by Fgf10. These findings reveal a Tbx1-dependent transcriptional and signaling network in the cardiac outflow tract that renders mouse cardiovascular development more susceptible than craniofacial development to a reduction in Tbx1 dose, similar to humans with del22q11.

The impact of cardiac surgery in patients with trisomy 18 and trisomy 13 in Japan

Congenital heart defects (CHD) are very common in patients with trisomy 18 (T18) and trisomy 13 (T13). The surgical indication of CHD remains controversial since the natural history of these trisomies is documented to be poor. To investigate the outcome of CHD in patients with T18 and T13, we collected and evaluated clinical data from 134 patients with T18 and 27 patients with T13 through nationwide network of Japanese Society of Pediatric Cardiology and Cardiac Surgery. In patients with T18, 23 (17%) of 134 were alive at this survey. One hundred twenty‐six (94%) of 134 patients had CHDs. The most common CHD was ventricular septal defect (VSD, 59%). Sixty‐five (52%) of 126 patients with CHD developed pulmonary hypertension (PH). Thirty‐two (25%) of 126 patients with CHD underwent cardiac surgery and 18 patients (56%) have survived beyond postoperative period. While palliative surgery was performed in most patients, six cases (19%) underwent intracardiac repair for VSD. Operated patients survived longer than those who did not have surgery (P < 0.01). In patients with T13, 5 (19%) of 27 patients were alive during study period. Twenty‐three (85%) of 27 patients had CHD and 13 (57%) of 27 patients had PH. Atrial septal defect was the most common form of CHD (22%). Cardiac surgery was done in 6 (26%) of 23 patients. In this study, approximately a quarter of patients underwent surgery for CHD in both trisomies. Cardiac surgery may improve survival in selected patients with T18.

Frequent association of 22q11.2 deletion with tetralogy of Fallot

Chromosome 22q11.2 deletion causes DiGeorge syndrome, velocardiofacial syndrome, conotruncal anomaly face syndrome with tetralogy of Fallot (TOF), and sporadic or familial TOF. To determine the prevalence and clinical importance of the 22q11.2 deletion in TOF, a series of 212 Japanese TOF patients was studied. The type of pulmonary blood supply, which may lead to various clinical outcomes, and other additional anomalies were evaluated clinically. The 22q11.2 deletion was diagnosed by fluorescence in situ hybridization with N25 and TUPLE1 probes. Of the 212 patients examined, 28 (13%) had a 22q11.2 deletion, the frequency being higher than that in TOF patients with trisomy 21. The prevalence of the deletion in TOF patients with pulmonary atresia (PA) plus major aortico-pulmonary collateral arteries (MAPCA) was significantly higher than the value in patients with PA plus patent ductus arteriosus (PDA) (P = 0.04) or with pulmonary stenosis (PS) (P < 0.0001). All 28 patients with 22q11.2 deletion had one or more extracardiac abnormalities. Four of 9 patients with the 22q11.2 deletion and TOF-PA-MAPCA suffered from bronchomalacia, while none of 19 patients with TOF-PA-PDA or TOF-PS manifested bronchomalacia (P = 0.006). These results indicate that 22q11.2 deletion is the most frequent cause of syndromic TOF, especially for TOF-PA-MAPCA, and bronchomalacia is the clinically most important associated anomaly in TOF-PA-MAPCA patients.

Phenotypic discordance in monozygotic twins with 22q11.2 deletion

We report on male monozygotic twins with 22q11.2 deletion and discordant phenotypes. The twins had twin-to-twin transfusion syndrome. Twin 1, the smaller of the pair, had Tetralogy of Fallot, a characteristic facial appearance, swallowing dysfunction, anal atresia, short stature, and mental retardation, whereas twin 2 had a characteristic facial appearance but no other signs of the 22q11 deletion syndrome. Fluorescence in situ hybridization analysis showed a microdeletion on chromosome 22q11.2 in both twins. Zygosity analysis gave a probability of monozygosity greater than 99.999%. These observations indicate that environmental factors or postzygotic events play a role in the phenotypic variability in the twins.

Tbx1 is Regulated by Forkhead Proteins in the Secondary Heart Field

Transcriptional regulation in a tissue‐specific and quantitative manner is essential for developmental events, including those involved in cardiovascular morphogenesis. Tbx1 is a T‐box–containing transcription factor that is responsible for many of the defects observed in 22q11 deletion syndrome in humans. Tbx1 is expressed in the secondary heart field (SHF) and is essential for cardiac outflow tract (OFT) development. We previously reported that Tbx1 is regulated by sonic hedgehog by means of forkhead (Fox) transcription factors in the head mesenchyme and pharyngeal endoderm, but how it is regulated in the SHF is unknown. Here, we show that Tbx1 expression in the SHF is regulated by Fox proteins through a combination of two evolutionarily conserved Fox binding sites in a dose‐dependent manner. Cell fate analysis using the Tbx1 enhancer suggests that SHF‐derived Tbx1‐expressing cells contribute extensively to the right ventricular myocardium as well as the OFT during early development and ultimately give rise to the right ventricular infundibulum, pulmonary trunk, and pulmonary valves. These results suggest that Fox proteins are involved in most, if not all, Tbx1 expression domains and that Tbx1 marks a subset of SHF‐derived cells, particularly those that uniquely contribute to the right‐sided outflow tract and proximal pulmonary artery. Developmental Dynamics 235:701–710, 2006.

Hand2 function in second heart field progenitors is essential for cardiogenesis

Cardiogenesis involves the contributions of multiple progenitor pools, including mesoderm-derived cardiac progenitors known as the first and second heart fields. Disruption of genetic pathways regulating individual subsets of cardiac progenitors likely underlies many forms of human cardiac malformations. Hand2 is a member of the basic helix loop helix (bHLH) family of transcription factors and is expressed in numerous cell lineages that contribute to the developing heart. However, the early embryonic lethality of Hand2-null mice has precluded lineage-specific study of its function in myocardial progenitors. Here, we generated and used a floxed allele of Hand2 to ablate its expression in specific cardiac cell populations at defined developmental points. We found that Hand2 expression within the mesoderm-derived second heart field progenitors was required for their survival and deletion in this domain recapitulated the complete Hand2-null phenotype. Loss of Hand2 at later stages of development and in restricted domains of the second heart field revealed a spectrum of cardiac anomalies resembling forms of human congenital heart disease. Molecular analyses of Hand2 mutant cells revealed several genes by which Hand2 may influence expansion of the cardiac progenitors. These findings demonstrate that Hand2 is essential for survival of second heart field progenitors and that the graded loss of Hand2 function in this cardiac progenitor pool can cause a spectrum of congenital heart malformation.

Sonic Hedgehog Is Essential for First Pharyngeal Arch Development

The secreted protein sonic hedgehog (Shh) is essential for normal development of many organs. Targeted disruption of Shh in mouse leads to near complete absence of craniofacial skeletal elements at birth, and mutation of SHH in human causes holoprosencephaly (HPE), frequently associated with defects of derivatives of pharyngeal arches. To investigate the role of Shh signaling in early pharyngeal arch development, we analyzed Shh mutant embryos using molecular markers and found that the first pharyngeal arch (PA1) was specifically hypoplastic and fused in the midline, and remaining arches were well formed at embryonic day (E) 9.5. Molecular analyses using specific markers suggested that the growth of the maxillary arch and proximal mandibular arch was severely defective in Shh-null PA1, whereas the distal mandibular arch was less affected. TUNEL assay revealed an increase in the number of apoptotic signals in PA1 of Shh mutant embryos. Ectodermal expression of fibroblast growth factor (Fgf)-8, a cell survival factor for pharyngeal arch mesenchyme, was down-regulated in the PA1 of Shh mutants. Consistent with this observation, downstream transcriptional targets of Fgf8 signaling in neural crest–derived mesenchyme, including Barx1, goosecoid, and Dlx2, were also down-regulated in Shh-null PA1. These results demonstrate that epithelial-mesenchymal signaling and transcriptional events coordinated by Shh, partly via Fgf8, is essential for cell survival and tissue outgrowth of the developing PA1.

Bronchomalacia associated with pulmonary atresia, ventricular septal defect and major aortopulmonary collateral arteries, and chromosome 22q11.2 deletion

Respiratory distress is one of the major complications in young infants with pulmonary atresia, ventricular septal defect and major aortopulmonary collateral arteries (PA‐VSD‐MAPCA); however, its aetiology remains obscure. We have previously reported an association of bronchomalacia with PA‐VSD‐MAPCA in patients with a hemizygous deletion of chromosome 22q11.2 (del.22q11). To clarify the clinical relevance of bronchomalacia in patients with PA‐VSD‐MAPCA and del.22q11, we reviewed the clinical and laboratory records of four patients with PA‐VSD‐MAPCA who had del.22q11 and bronchomalacia. External bronchial compression by anomalous patterning of the aorta and MAPCA was documented in three of the four patients, using combinatorial examination of angiocardiography, bronchography, fibreoptic bronchoscopy and magnetic resonance imaging. One of the four patients died suddenly of severe respiratory distress at 4 years of age, while the remaining three were inoperable for complete surgical repair. Our study indicates that bronchomalacia as a result of external vascular compression may be an aetiology of early‐onset respiratory distress in some patients with PA‐VSD‐MAPCA and del.22q11, and can significantly affect the clinical outcome.

Mechanisms underlying early development of pulmonary vascular obstructive disease in Down syndrome: An imbalance in biosynthesis of thromboxane A2 and prostacyclin.

Patients with Down syndrome (DS) and a left‐to‐right shunt often develop early severe pulmonary hypertension (PH) and pulmonary vascular obstructive disease (PVOD); the pathophysiological mechanisms underlying the development of these complications are yet to be determined. To investigate the mechanisms, we evaluated the biosynthesis of thromboxane (TX) A2 and prostacyclin (PGI2) in four groups of infants, cross‐classified as shown below, by measuring the urinary excretion levels of 11‐dehydro‐TXB2 and 2,3‐dinor‐6‐keto‐PGF1α: DS infants with a left‐to‐right shunt and PH (D‐PH, n = 18), DS infants without congenital heart defect (D‐C, n = 8), non‐DS infants with a left‐to‐right shunt and PH (ND‐PH, n = 12), and non‐DS infants without congenital heart defect (ND‐C, n = 22). The urinary excretion ratios of 11‐dehydro‐TXB2 to 2,3‐dinor‐6‐keto‐PGF1α in the D‐PH, D‐C, ND‐PH, and ND‐C groups were 7.69, 4.71, 2.10, and 2.27, respectively. The ratio of 11‐dehydro‐TXB2 to 2,3‐dinor‐6‐keto‐PGF1α was higher in the presence of DS (P < 0.001), independently of the presence of PH (P = 0.297). The predominant biosynthesis of TXA2 over PGI2, leading to vasoconstriction, was observed in DS infants, irrespective of the presence/absence of PH. This imbalance in the biosynthesis of vasoactive eicosanoids may account for the rapid progression of PVOD in DS infants with a left‐to‐right shunt.

Ventricular septal defect associated with microdeletions of chromosome 22q11.2.

Microdeletions of chromosome 22q11.2 (del.22q11) cause DiGeorge syndrome, velo‐cardio‐facial syndrome, and conotruncal anomaly face syndrome, which are commonly associated with conotruncal heart anomalies. Approximately 15% of the patients manifest ventricular septal defect (VSD), and the conal–septal type of VSD has been proposed to be associated with del.22q11, since it is categorized as a conotruncal anomaly. However, the types of VSD associated with del.22q11 remain poorly studied. The purpose of this study is to assess whether conal–septal VSD or other types of VSDs are associated with del.22q11. We analyzed the chromosomes of 22 consecutive patients with conal–septal VSD, prospectively, and evaluated the types of VSD observed in 3 patients with del.22q11, retrospectively. Del.22q11 was not detected in any of the 22 patients with conal–septal VSD. All the VSDs observed in the 3 patients with del.22q11 were a perimembranous type of VSD, which is not a conotruncal anomaly. Our results suggest that perimembranous VSD can be associated with del.22q11, but del.22q11 is not a common cause of conal–septal VSD.