Left–right patterning in congenital heart disease beyond heterotaxy

Gabriel, George C.; Lo, Cecilia

doi:10.1002/ajmg.c.31768

Cited by 21 publications

(14 citation statements)

References 48 publications

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“…Prevalence figures for heterotaxy are estimated at 1/8000-1/12,000 live births [12,16,17]. Although classic heterotaxy accounts for only 3% of all congenital heart defects, gene mutations causing heterotaxy are also known to result in isolated cardiovascular malformations with no other visceral abnormalities, suggesting that the real prevalence of genetic heterotaxy is probably higher [19,23]. Two general types of heterotaxy, called isomerism, are described, although their exact morphology and its resulting abnormalities vary from patient to patient [11,19].…”

Section: Heterotaxymentioning

confidence: 99%

Atypical Brain Asymmetry in Human Situs Inversus: Gut Feeling or Real Evidence?

2021

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The alignment of visceral and brain asymmetry observed in some vertebrate species raises the question of whether this association also exists in humans. While the visceral and brain systems may have developed asymmetry for different reasons, basic visceral left–right differentiation mechanisms could have been duplicated to establish brain asymmetry. We describe the main phenotypical anomalies and the general mechanism of left–right differentiation of vertebrate visceral and brain laterality. Next, we systematically review the available human studies that explored the prevalence of atypical behavioral and brain asymmetry in visceral situs anomalies, which almost exclusively involved participants with the mirrored visceral organization (situs inversus). The data show no direct link between human visceral and brain functional laterality as most participants with situs inversus show the typical population bias for handedness and brain functional asymmetry, although an increased prevalence of functional crowding may be present. At the same time, several independent studies present evidence for a possible relation between situs inversus and the gross morphological asymmetry of the brain torque with potential differences between subtypes of situs inversus with ciliary and non-ciliary etiologies.

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Section: Heterotaxymentioning

confidence: 99%

Atypical Brain Asymmetry in Human Situs Inversus: Gut Feeling or Real Evidence?

2021

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“…The heart is particularly sensitive to disturbances in left-right patterning and the most severe symptoms of laterality disorders are related to defects in cardiac patterning [3]. The reason for this is perhaps two-fold: firstly, the heart plays such a pivotal role in our survival that anything affecting its function has dire consequences [4] and, secondly, the organ itself exhibits considerable asymmetry and is, therefore, highly sensitive to left-right patterning defects [5]. A range of laterality defects can affect the heart, and these include AV valve defects, atrial septal defects, ventricular septal defects, transposition of the great arteries, double-outlet right ventricle and outflow tract defects [6].…”

Section: Introductionmentioning

confidence: 99%

Getting to the Heart of Left–Right Asymmetry: Contributions from the Zebrafish Model

Smith

Uribe

2021

JCDD

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The heart is laterally asymmetric. Not only is it positioned on the left side of the body but the organ itself is asymmetric. This patterning occurs across scales: at the organism level, through left–right axis patterning; at the organ level, where the heart itself exhibits left–right asymmetry; at the cellular level, where gene expression, deposition of matrix and proteins and cell behaviour are asymmetric; and at the molecular level, with chirality of molecules. Defective left–right patterning has dire consequences on multiple organs; however, mortality and morbidity arising from disrupted laterality is usually attributed to complex cardiac defects, bringing into focus the particulars of left–right patterning of the heart. Laterality defects impact how the heart integrates and connects with neighbouring organs, but the anatomy of the heart is also affected because of its asymmetry. Genetic studies have demonstrated that cardiac asymmetry is influenced by left–right axis patterning and yet the heart also possesses intrinsic laterality, reinforcing the patterning of this organ. These inputs into cardiac patterning are established at the very onset of left–right patterning (formation of the left–right organiser) and continue through propagation of left–right signals across animal axes, asymmetric differentiation of the cardiac fields, lateralised tube formation and asymmetric looping morphogenesis. In this review, we will discuss how left–right asymmetry is established and how that influences subsequent asymmetric development of the early embryonic heart. In keeping with the theme of this issue, we will focus on advancements made through studies using the zebrafish model and describe how its use has contributed considerable knowledge to our understanding of the patterning of the heart.

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“…In many cases, these asymmetries are evolutionarily conserved and necessary for physiological function, indicating that the formation of LR asymmetry is an essential phase of vertebrate organogenesis. Indeed, abnormal LR axis formationa condition known as heterotaxyis associated with some of the most common and severe structural birth defects, including complex congenital heart defects (CHDs), intestinal malrotation, extrahepatic biliary atresia, asplenia/polysplenia and other anomalies (Bartram et al, 2005;Chinya et al, 2019;Desgrange et al, 2018;Gabriel and Lo, 2020;Kothari, 2014;Ticho et al, 2000). Therefore, understanding the mechanisms that shape individual organ lateralities is not only necessary for illuminating the morphogenesis of numerous organs but could also be crucial for explaining the etiology of a wide variety of birth defects.…”

Section: Introductionmentioning

confidence: 99%

The twists and turns of left-right asymmetric gut morphogenesis

2020

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Many organs develop left-right asymmetric shapes and positions that are crucial for normal function. Indeed, anomalous laterality is associated with multiple severe birth defects. Although the events that initially orient the left-right body axis are beginning to be understood, the mechanisms that shape the asymmetries of individual organs remain less clear. Here, we summarize new evidence challenging century-old ideas about the development of stomach and intestine laterality. We compare classical and contemporary models of asymmetric gut morphogenesis and highlight key unanswered questions for future investigation.

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Left–right patterning in congenital heart disease beyond heterotaxy

Cited by 21 publications

References 48 publications

Atypical Brain Asymmetry in Human Situs Inversus: Gut Feeling or Real Evidence?

Atypical Brain Asymmetry in Human Situs Inversus: Gut Feeling or Real Evidence?

Getting to the Heart of Left–Right Asymmetry: Contributions from the Zebrafish Model

The twists and turns of left-right asymmetric gut morphogenesis

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