Cellular and Molecular Pathobiology of Cardiovascular Disease focuses on the pathophysiology of common cardiovascular disease in the context of its underlying mechanisms and molecular biology. This book has been developed from the editors' experiences teaching an advanced cardiovascular pathology course for PhD trainees in the biomedical sciences, and trainees in cardiology, pathology, public health, and veterinary medicine. No other single text-reference combines clinical cardiology and cardiovascular pathology with enough molecular content for graduate students in both biomedical research and clinical departments. The text is complemented and supported by a rich variety of photomicrographs, diagrams of molecular relationships, and tables. It is uniquely useful to a wide audience of graduate students and post-doctoral fellows in areas from pathology to physiology, genetics, pharmacology, and more, as well as medical residents in pathology, laboratory medicine, internal medicine, cardiovascular surgery, and cardiology. - Explains how to identify cardiovascular pathologies and compare with normal physiology to aid research- Gives concise explanations of key issues and background reading suggestions- Covers molecular bases of diseases for better understanding of molecular events that precede or accompany the development of pathology
Molecular Basis of Cardiac Development
Laura A. Dyer, PhD1, Ivan Moskowitz, MD, PhD2 and Cam Patterson, MD, MBA1, 1McAllister Heart Institute, University of North Carolina at Chapel Hill, NC, USA, 2Departments of Pediatrics and Pathology, The University of Chicago, IL, USA
Abstract
Development of the mature heart is a complex process that turns a field of mesodermal progenitors into a four-chambered organ with divided circulation. When this process goes awry, cardiac anomalies arise, and abnormalities of the heart present at birth, or congenital heart disease (CHD), have been described for centuries. CHD is highly prevalent, representing the most frequent birth defect worldwide. Tremendous strides have been made in understanding the developmental biology of cardiac morphogenesis and the human genetics of CHD. These fields of research are beginning to merge to provide an understanding of the molecular mechanisms underlying CHD. In this chapter, we present the major developmental and molecular pathways of heart formation and how they are related to human CHDs that arise when these pathways are perturbed. While CHD is generally considered conceptually as a single disease, it is much more accurate to consider CHD as a compilation of numerous distinct specific diseases, each with their own developmental and molecular etiology.
Keywords
arterial pole; atria; cardiac valves; conduction system; congenital heart defect; coronary vasculature; heart development; heart field; venous pole; ventricles
Acknowledgments
We would first like to apologize to the many authors whose studies were excluded due to space constraints. We would like to thank Dr. Andrea Portbury and Chelsea Cyr for critical reading of the manuscript.
The Heart Fields and Heart Tube Formation
The heart begins simply as a bilateral field within the lateral plate mesoderm (Figure 1.1, Table 1.1). As the early embryo undergoes formation of the gut-tube, these bilateral fields migrate toward the midline, where the cranial-most aspect of the fields will fuse ventrally to form the outer curvature of the heart tube.1 These fields will continue to migrate together, with more of the heart fields contributing to the forming tube, until the dorsal aspect of the heart fields fuse to form a closed tube.1 The initial contributors to the heart tube are known as the first heart field.2 The first heart field gives rise to the left ventricle, with some contributions to the atria and the right ventricle.3 Additional heart field progenitors from the lateral plate mesoderm continue to add to the arterial and venous poles of the heart tube; these later-adding cells are known as the second heart field. The second heart field gives rise to most of the right ventricle and atria, the most distal myocardium that surrounds the aorta and pulmonary artery, and the most proximal smooth muscle that contributes to the tunica media of the great arteries.2
FIGURE 1.1 An overview of heart development. (A) The heart fields are specified as bilateral fields within the lateral plate mesoderm. The cranial-most aspect (asterisks) will migrate toward the midline first; this seam is depicted by the gray dashed line in B. (B) The heart tube closes ventrally, and cells continue to add from the heart fields. The dorsal aspect of the heart tube will pinch off last. After dorsal closure, additional cells can only be added via the venous (IFT, inflow tract) and arterial (OFT, outflow tract) poles. (C) As additional cells add to the heart tube, the heart tube begins to undergo looping, and the ventral midline becomes the outer curvature of the heart. During looping, the endocardial cushions begin forming in the atrioventricular canal and outflow tract. The atrioventricular canal separates the common atrium (A) from the common ventricle (V). (D) At the end of looping, the atrioventricular cushions are aligned dorsal to the outflow tract cushions, allowing connections between the left atrium and ventricle (LA and LV, respectively) and the right atrium and ventricle (RA and RV, respectively). As the outflow tract is septated, it also undergoes rotation to align the aorta with the left ventricle. Septa form between the ventricles and between the atria. (E) In the mature four-chambered heart, the aorta (Ao) serves as the outlet for the left side of the heart, and the pulmonary artery (PA) serves as the outlet for the right side of the heart.
TABLE 1.1
Major Developmental Time Points in Humans and Common Experimental Models
The major stages in cardiovascular development are presented for humans and the most commonly used animal models.
∗Because the heart tube begins forming as a trough that then closes dorsally, contractions are observed prior to the pinching off of the fully formed heart tube.
†The foramen ovale is still open at this stage. This fenestration is closed at the stages listed for the other species. CS, Carnegie stage219; E, embryonic day; HH, Hamburger-Hamilton stage220; Stage, Nieuwkoop and Faber stage221; hpf, hours post-fertilization. See cited references for more details.
Signaling Pathways in Heart Field Specification
The Wnt Pathway
The Wnt family includes the canonical pathway, the non-canonical pathway (also known as the planar cell polarity pathway), and the Wnt/calcium pathway (Figure 1.2). Both the canonical and non-canonical pathways have well-established roles in heart field specification. Temporal waves of canonical and non-canonical Wnt signaling play distinct roles during cardiac specification and morphogenesis. As the heart field forms from the primitive streak, Wnt3a is expressed in the primitive streak and serves as a repulsive cue to the forming heart field.4 Experiments performed in Xenopus, due to its ease of manipulation and genetic tractability,5 have shown that the early repression of Wnt signaling in the Xenopus animal cap (i.e., in the ectodermal roof of the blastocele prior to heart field specification) via Dkk-1 and Crescent is necessary for initiation of transcription of cardiac transcription factors Nkx2.5 and Tbx5 and myocardial-specific proteins troponin I and myosin heavy chain α.6 However, later in cardiac development, canonical Wnt signaling in embryonic mice at E8.75 promotes Nkx2.5, Islet1, and Baf60c within the entire heart.7 Due to the genetic similarity between Xenopus and mouse, these differences likely reflect different temporal requirements for Wnt signaling as opposed to species-specific differences.5 In the second heart field, non-canonical Wnts 5a and 11, which act through the non-canonical planar cell polarity pathway, are expressed slightly later in development and co-operatively repress the canonical Wnt pathway while also promoting expression of Islet1 and Hand2, whose expression serves to ‘mark’ the heart field;8 as such, these genes are commonly referred to as cardiac markers. Both the repression of the canonical Wnts and the induction of the heart field markers require β-catenin in the second heart field.8 Wnt5a and Wnt11 also promote proliferation within this progenitor region.8 After the heart tube forms, Wnt-stabilized β-catenin is necessary in the Islet1-expressing second heart field cells to maintain their progenitor status.9 Loss of either β-catenin or Wnt signaling in the second heart field leads to second heart field defects, including right ventricular and outflow tract defects.9,10 Even if Wnt signaling is lost under cells expressing one of the first markers of differentiated cardiomyocytes, Mesp1, second heart field proliferation is decreased, and Islet-1 expression is down-regulated.11 Conversely, overexpressing β-catenin under the Mesp1 promoter expands the Islet-1-positive second heart field and promotes proliferation.11 Later, Wnt5a specifically acts upstream of the disheveled/planar cell polarity pathway to regulate the addition of the second heart field to the arterial pole.12 In addition, Wnt signaling also promotes bone morphogenetic protein (BMP) 4 and the non-canonical Wnt 11, which promote myocardial differentiation.9,11 Thus, the Wnt pathway is critical for inducing heart field formation, maintaining progenitor status and promoting myocardial differentiation.
FIGURE 1.2 Wnt signaling pathway. In both the canonical and non-canonical (planar cell polarity) pathways, extracellular Wnt ligands bind to the transmembrane receptor Frizzled. In the canonical pathway, Frizzled forms a complex with Dishevelled and additional components, leading to β-catenin stabilization and translocation to the nucleus; β-catenin then promotes Wnt-induced gene expression, such as Nkx2.5 and Islet1. In contrast, in the non-canonical pathway, Frizzled and Dishevelled act on a different set of intracellular signaling molecules (e.g., Rho, Rac) to promote a different set of genes and to inhibit the canonical pathway.
Retinoic Acid
One of the earliest required signaling pathways is the retinoic acid pathway. RALDH2, the enzyme that synthesizes retinoic acid, is restricted within the lateral plate mesoderm to a region nearest to the heart field.13,14 Expression of RALDH2 progresses in a cranial–caudal direction during heart field induction and heart tube formation and establishes the posterior boundary of...
| Erscheint lt. Verlag | 23.12.2013 |
|---|---|
| Sprache | englisch |
| Themenwelt | Medizinische Fachgebiete ► Innere Medizin ► Kardiologie / Angiologie |
| Medizin / Pharmazie ► Medizinische Fachgebiete ► Pharmakologie / Pharmakotherapie | |
| Studium ► 1. Studienabschnitt (Vorklinik) ► Physiologie | |
| Studium ► 2. Studienabschnitt (Klinik) ► Pathologie | |
| Naturwissenschaften ► Biologie ► Humanbiologie | |
| Technik | |
| ISBN-10 | 0-12-405525-7 / 0124055257 |
| ISBN-13 | 978-0-12-405525-4 / 9780124055254 |
| Informationen gemäß Produktsicherheitsverordnung (GPSR) | |
| Haben Sie eine Frage zum Produkt? |
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