Formation of Endocardial Cushions

The endocardial cushions are one of the most important transient embryonic structures in the developing heart. They serve as the primary building blocks for atrioventricular (AV) septation, valve formation, and outflow tract remodeling. Despite their temporary nature, endocardial cushions have a permanent influence on the architecture and function of the heart, as they ultimately give rise to critical cardiac components such as the atrioventricular septa, valves, and membranous interventricular septum.

This post explores the formation of endocardial cushions in detail, including their origin, cellular contributions, molecular regulation, morphogenetic events, and clinical implications.

1. Introduction

The formation of endocardial cushions is a pivotal event in cardiac morphogenesis, taking place during the 4th and 5th weeks of human embryonic development. The process begins with the accumulation of extracellular matrix (ECM) between the endocardium and myocardium, a substance known as cardiac jelly, within the atrioventricular (AV) canal and outflow tract.

Once formed, the cushions act as morphogenetic primordia that will later fuse, remodel, and transform into the atrioventricular septa and valves, as well as contribute to outflow tract septation. Any disruption of this process can result in severe congenital malformations such as atrioventricular septal defects (AVSD), persistent truncus arteriosus, or valvular stenosis/regurgitation.

2. Embryonic Context

Before endocardial cushion formation, the heart exists as a linear heart tube consisting of:

Sinus venosus
Primitive atrium
Primitive ventricle
Bulbus cordis
Truncus arteriosus

As the heart undergoes looping (days 23–28), the AV canal is positioned centrally, and it becomes a crucial site where endocardial cushion development is initiated.

2.1 Cardiac Jelly Deposition

Cardiac jelly is a specialized ECM-rich layer secreted by the myocardium and located between the endocardium (inner lining) and myocardium (outer muscle layer). It consists of:

Hyaluronic acid
Glycoproteins
Proteoglycans
Collagen fibers

This jelly serves as a scaffold for cell migration and cushion formation.

3. Initiation of Endocardial Cushions

3.1 Regional Swelling

At approximately week 4 of gestation, cardiac jelly within the AV canal and outflow tract begins to swell at specific sites, forming localized thickenings known as the superior (dorsal) and inferior (ventral) endocardial cushions. Additional lateral cushions form slightly later.

3.2 Endocardial-to-Mesenchymal Transformation (EMT)

One of the most important steps is the transformation of endocardial cells into mesenchymal cells:

Endocardial cells overlying the cushions receive myocardial signals (e.g., BMP2, TGF-β, Notch)
They lose their tight junctions, detach, and invade the cardiac jelly
This process is known as endocardial EMT
The result is a population of mesenchymal cells that populate the cushions, giving them a cellular, proliferative, and migratory character

4. Growth and Remodeling of Cushions

4.1 Cellular Contribution

Cushions are populated not only by EMT-derived mesenchyme but also by:

Cardiac neural crest cells (especially in outflow tract cushions)
Epicardial-derived cells (EPDCs) in later stages
Endothelial progenitors that migrate into the ECM

4.2 Fusion of Cushions

The superior and inferior cushions grow toward each other and fuse in the midline by the end of the 5th week. This fusion divides the single AV canal into right and left AV orifices, thereby aligning the atria with their respective ventricles.

5. Morphogenetic Roles of Endocardial Cushions

5.1 Formation of AV Septa

Cushion fusion contributes to the atrioventricular septum, which separates the right and left AV canals. This is essential for:

Proper alignment of atria and ventricles
Prevention of blood mixing
Establishing a pathway for future valve development

5.2 Contribution to Interventricular Septum

The membranous interventricular septum forms partly from cushion tissue. This is critical because defects in cushion formation can lead to membranous ventricular septal defects (VSDs), one of the most common congenital heart malformations.

5.3 Valve Formation

Endocardial cushions give rise to:

Mitral and tricuspid valve leaflets
Chordae tendineae and papillary muscles (through remodeling)
Semilunar valves (in the outflow tract cushions)

Valve formation involves cushion elongation, thinning, and sculpting into leaflet-like structures that will later support unidirectional blood flow.

6. Molecular Regulation

6.1 Key Signaling Pathways

Several molecular pathways regulate cushion formation:

BMP2 (Bone Morphogenetic Protein 2): Induces EMT in endocardial cells
TGF-β (Transforming Growth Factor-beta): Drives mesenchymal cell proliferation and ECM production
Notch signaling: Maintains endocardial cell plasticity, enabling EMT
VEGF (Vascular Endothelial Growth Factor): Balances EMT; too much inhibits mesenchymal transformation
Wnt/β-catenin signaling: Promotes cushion cell proliferation

6.2 Transcription Factors

GATA4, TBX2, TBX20: Control cushion positioning and growth
SOX9: Promotes mesenchymal differentiation
NFATc1: Maintains endocardial identity before EMT

7. Outflow Tract Cushions

While the AV cushions are crucial for canal partitioning, outflow tract (conotruncal) cushions are equally important for separating systemic and pulmonary circulation. These cushions:

Arise partly from neural crest-derived mesenchyme
Fuse to form the aorticopulmonary septum
Divide the truncus arteriosus into aorta and pulmonary trunk

Defects here lead to conotruncal anomalies such as tetralogy of Fallot or persistent truncus arteriosus.

8. Hemodynamic Forces and Cushion Maturation

Blood flow through the heart exerts shear stress and pressure, which are crucial for:

Proper cushion growth
Remodeling into thin valve leaflets
Alignment of AV canal with ventricles

Abnormal flow patterns (e.g., in embryonic heart defects) can lead to hypoplastic cushions or misaligned valves.

9. Clinical Significance

9.1 Atrioventricular Septal Defects (AVSD)

Failure of cushion fusion causes complete AV canal defect with:

Common AV valve
Incomplete separation of right and left AV orifices
Often seen in Down syndrome (trisomy 21)

9.2 Valvular Defects

Abnormal cushion remodeling leads to:

Mitral or tricuspid atresia
Bicuspid aortic valve (if outflow tract cushions are affected)
Congenital valve stenosis or regurgitation

9.3 Ventricular Septal Defects

Membranous VSDs occur if the cushion contribution to the interventricular septum fails.

10. Diagnostic and Research Perspectives

Fetal echocardiography can visualize AV canal and cushion swelling
3D ultrasound and MRI are emerging tools for detailed fetal heart imaging
Animal models (mouse, chick, zebrafish) are used to study cushion morphogenesis and gene function

11. Experimental Insights

Genetic knockout studies in mice have shown:

BMP2 or TGF-β2 deficiency leads to absent cushions
Notch1 knockout causes severe endocardial defects
Neural crest ablation disrupts outflow tract cushion fusion, causing conotruncal malformations

These models underline the multifactorial control of cushion formation.

12. Summary Table

Stage	Event	Key Regulators
Week 4	Cardiac jelly deposition	Myocardial signaling
Week 4–5	Endocardial EMT	BMP2, TGF-β, Notch
Week 5	Cushion cellularization	Mesenchymal proliferation
Week 5–6	Cushion fusion	Mechanical forces, ECM remodeling
Week 6–8	Valve sculpting	Wnt, VEGF, Sox9
Week 7–8	Septation complete	AV septum formed