Intrinsic cellular chirality regulates left–right symmetry breaking during cardiac looping

Ray, Poulomi; Chin, Amanda S.; Worley, Kathryn E.; Fan, Jie; Kaur, Gurleen; Wu, Mingfu; Wan, Leo Q.

doi:10.1073/pnas.1808052115

Cited by 56 publications

(71 citation statements)

References 61 publications

(87 reference statements)

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“…For example, the dextral looping of the zebrafish heart is controlled by a heart-intrinsic cytoskeletondependent mechanism (Desgrange et al, 2018;Noël et al, 2013). Thus, asymmetric information is transferred from smaller to larger scales multiple times independently within the same embryo (Chin et al, 2018;Ray et al, 2018), rather than emerging in a single symmetry-breaking event.…”

Section: Discussionmentioning

confidence: 99%

Making and breaking symmetry in development, growth and disease

Grimes

2019

Development

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Consistent asymmetries between the left and right sides of animal bodies are common. For example, the internal organs of vertebrates are left-right (L-R) asymmetric in a stereotyped fashion. Other structures, such as the skeleton and muscles, are largely symmetric. This Review considers how symmetries and asymmetries form alongside each other within the embryo, and how they are then maintained during growth. I describe how asymmetric signals are generated in the embryo. Using the limbs and somites as major examples, I then address mechanisms for protecting symmetrically forming tissues from asymmetrically acting signals. These examples reveal that symmetry should not be considered as an inherent background state, but instead must be actively maintained throughout multiple phases of embryonic patterning and organismal growth.

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Section: Discussionmentioning

confidence: 99%

Making and breaking symmetry in development, growth and disease

Grimes

2019

Development

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“…Chick embryonic cardiac cells exhibit intrinsic cell chirality prior to looping, which ensures a dominant clockwise rotation. Like the Drosophila hindgut, these cells exhibit polarized Cadherin and Myosin molecules prior to cardiac looping (Ray et al 2018). Further, it is known that L/R asymmetry in vertebrates is dictated by the floor plate, an analogous embryonic landmark to the Drosophila midline cells.…”

Section: Hindgut Developmentmentioning

confidence: 99%

Physiology, Development, and Disease Modeling in the Drosophila Excretory System

et al. 2020

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The insect excretory system contains two organ systems acting in concert: the Malpighian tubules and the hindgut perform essential roles in excretion and ionic and osmotic homeostasis. For over 350 years, these two organs have fascinated biologists as a model of organ structure and function. As part of a recent surge in interest, research on the Malpighian tubules and hindgut of Drosophila have uncovered important paradigms of organ physiology and development. Further, many human disease processes can be modeled in these organs. Here, focusing on discoveries in the past 10 years, we provide an overview of the anatomy and physiology of the Drosophila excretory system. We describe the major developmental events that build these organs during embryogenesis, remodel them during metamorphosis, and repair them following injury. Finally, we highlight the use of the Malpighian tubules and hindgut as accessible models of human disease biology. The Malpighian tubule is a particularly excellent model to study rapid fluid transport, neuroendocrine control of renal function, and modeling of numerous human renal conditions such as kidney stones, while the hindgut provides an outstanding model for processes such as the role of cell chirality in development, nonstem cell–based injury repair, cancer-promoting processes, and communication between the intestine and nervous system.

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“…Today, links between chirality at the molecular and organismal levels are slowly beginning to be understood [7][8][9][10]. Notably, between these two layers of biological chirality, chirality at the cellular level was discovered [10][11][12][13][14][15][16][17].…”

Section: Chirality Appears As a Hierarchical Structure In Biologymentioning

confidence: 99%

“…Cell chirality has roles in vertebrate LR asymmetric development in parallel with other known mechanisms, such as nodal flow and LR asymmetric proton influx [56,57]. For example, chick cardiac cells show an intrinsic cell chirality that is responsible for the LR asymmetry break in cardiac looping [17]. In addition, cell chirality may be involved in the concordant organization of tissue, because the coexistence of cells with different enantiomorphic states of cell chirality within a tissue may introduce disharmony into the tissue's organization.…”

Section: Perspectivesmentioning

confidence: 99%

Cells with Broken Left–Right Symmetry: Roles of Intrinsic Cell Chirality in Left–Right Asymmetric Epithelial Morphogenesis

et al. 2019

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Chirality is a fundamental feature in biology, from the molecular to the organismal level. An animal has chirality in the left–right asymmetric structure and function of its body. In general, chirality occurring at the molecular and organ/organism scales has been studied separately. However, recently, chirality was found at the cellular level in various species. This “cell chirality” can serve as a link between molecular chirality and that of an organ or animal. Cell chirality is observed in the structure, motility, and cytoplasmic dynamics of cells and the mechanisms of cell chirality formation are beginning to be understood. In all cases studied so far, proteins that interact chirally with F-actin, such as formin and myosin I, play essential roles in cell chirality formation or the switching of a cell’s enantiomorphic state. Thus, the chirality of F-actin may represent the ultimate origin of cell chirality. Links between cell chirality and left–right body asymmetry are also starting to be revealed in various animal species. In this review, the mechanisms of cell chirality formation and its roles in left–right asymmetric development are discussed, with a focus on the fruit fly Drosophila, in which many of the pioneering studies were conducted.

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Intrinsic cellular chirality regulates left–right symmetry breaking during cardiac looping

Cited by 56 publications

References 61 publications

Making and breaking symmetry in development, growth and disease

Making and breaking symmetry in development, growth and disease

Physiology, Development, and Disease Modeling in the Drosophila Excretory System

Cells with Broken Left–Right Symmetry: Roles of Intrinsic Cell Chirality in Left–Right Asymmetric Epithelial Morphogenesis

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