Chiral blastomere arrangement dictates zygotic left–right asymmetry pathway in snails

Kuroda, Reiko; Endo, Bunshiro; Abe, Masanori; Shimizu, Miho

doi:10.1038/nature08597

Cited by 155 publications

(219 citation statements)

References 27 publications

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“…This proposal is also not consistent with published data on the timing of involvement of physiological events in the LR pathway (Yost, 1991;Fukumoto et al, 2005a;Fukumoto et al, 2005b;Adams et al, 2006;Danilchik et al, 2006;Vandenberg and Levin, 2010). primitive streak (Gardner, 1997(Gardner, , 2001, this work shows that the mouse embryo is not exempt from the importance of very early events for LR asymmetry. Importantly, this is the same outcome as seen in the experiments involving micromanipulation of blastomeres in snail (Kuroda et al, 2009) and C. elegans (Wood and Kershaw, 1991) embryos, providing more evidence that there are conserved mechanisms for establishing LR asymmetry across phyla. While much work remains to be done to characterize other aspects of this laterality phenotype, it is clear that events in the mouse taking place 7 days before the appearance of the ciliated node can influence aspects of asymmetry.…”

Section: The Mouse As a Model For Mammalian Asymmetrysupporting

confidence: 68%

“…The links between intracellular (cytoskeleton-driven) polarity and LR asymmetry have grown stronger: recent data from snails, frogs and mice all suggest that a chiral cytoskeleton is established extremely early during development (Danilchik et al, 2006;Kuroda et al, 2009;Gardner, 2010), a remarkable example of a widely-conserved system that has relevance to invertebrate and even plant systems (Doss, 1978;Hashimoto, 2002;Abe et al, 2004;Levin, 2006;Oviedo and Levin, 2007). Interestingly, the role of a MTOC as the initiator of LR asymmetry is common to all three main models in the field, a largely unacknowledged common ground among the many interesting controversies about downstream amplification and coordination mechanisms.…”

Section: Discussionmentioning

confidence: 99%

“…The rapid redistribution of serotonin among blastomeres (Fukumoto et al, 2005b) leads to stable, specific gene expression cascades on the left side; a similar situation occurs in C. elegans, where the NSY-5 gap junction protein establishes transient connections for physiological signals that specify the permanent asymmetry in the structure and function of the AWC olfactory neurons (Chuang et al, 2007). Similarly, as very early cytoskeletal biases in Xenopus ultimately result in asymmetries of visceral organs , the transduction of chiral cytoskeletal activity into asymmetric Nodal induction has recently been demonstrated in snail embryos; alterations in spindle orientations by means of mechanical manipulations in early cleavage stage embryos alter the Nodal signaling pathway as well as handedness of shell coiling (Kuroda et al, 2009). Thus, while details of the early steps by which physiological asymmetries result in consistently different genetic programs on the left and right sides differ among phyla, a remarkably wide conservation is seen in the logic and molecular nature of the control systems by which biophysical, epigenetic signals are transformed into stable transcriptional states.…”

Section: Amplification: Bioelectric Redistribution Of Morphogens and mentioning

confidence: 99%

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Far from solved: A perspective on what we know about early mechanisms of left–right asymmetry

Vandenberg

Levin

2010

Developmental Dynamics

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Consistent laterality is a crucial aspect of embryonic development, physiology, and behavior. While strides have been made in understanding unilaterally expressed genes and the asymmetries of organogenesis, early mechanisms are still poorly understood. One popular model centers on the structure and function of motile cilia and subsequent chiral extracellular fluid flow during gastrulation. Alternative models focus on intracellular roles of the cytoskeleton in driving asymmetries of physiological signals or asymmetric chromatid segregation, at much earlier stages. All three models trace the origin of asymmetry back to the chirality of cytoskeletal organizing centers, but significant controversy exists about how this intracellular chirality is amplified onto cell fields. Analysis of specific predictions of each model and crucial recent data on new mutants suggest that ciliary function may not be a broadly conserved, initiating event in left-right patterning. Many questions about embryonic left-right asymmetry remain open, offering fascinating avenues for further research in cell, developmental, and evolutionary biology. Developmental Dynamics 239:3131-3146,

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Section: The Mouse As a Model For Mammalian Asymmetrysupporting

confidence: 68%

Section: Discussionmentioning

confidence: 99%

Section: Amplification: Bioelectric Redistribution Of Morphogens and mentioning

confidence: 99%

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Far from solved: A perspective on what we know about early mechanisms of left–right asymmetry

Vandenberg

Levin

2010

Developmental Dynamics

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“…The maternal inheritance is a crucial advantage as the chirality is determined at the early developmental stage. Recently, we proved that chirality is determined by a single locus (Hosoiri et al 2003;Kuroda, 2014;Kuroda et al 2009;Shibazaki et al 2004), although it had been postulated based on the early 20th century work (Boycott et al 1930;Sturtevant, 1923). Secondly, snails are hermaphrodite, reproducing offspring by self-and cross-fertilization, which is advantageous in tracing genetic traits.…”

Section: Introductionmentioning

confidence: 99%

“…As the species had not been well studied compared with Lymnaea peregra (Freeman & Lundelius, 1982) except for the detailed observation of development (Meshcheryakov, 1990), we studied the breeding behaviour (Hosoiri et al 2003), correlation of cleavage pattern and organismal morphology (Shibazaki et al 2004), cytoplasm injections to the 1-cell embryos of opposite chirality (Kuroda, 2014), cytoskeletal dynamics during spiral cleavages (Shibazaki et al 2004), expression of nodal-Pitx genes (Kuroda et al 2009), creation of mirrorimage healthy animals by twisting blastomeres at the third cleavage (Kuroda et al 2009), etc. We also constructed backcrossed congenic animals (Hosoiri et al 2003;Kuroda, 2014;Kuroda et al 2009;Shibazaki et al 2004) and carried out positional cloning in order to identify the handedness determining gene(s).…”

Section: Introductionmentioning

confidence: 99%

A twisting story: how a single gene twists a snail? Mechanogenetics

Kuroda

2015

Quart. Rev. Biophys.

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Abstract. Left-right (l-r) symmetry breaking and the establishment of asymmetric animal body plan during embryonic development are fundamental questions in nature. The molecular basis of l-r symmetry breaking of snails is a fascinating topic as it is determined by a maternal single handedness-determining locus at a very early developmental stage. This perspective describes the current state of the art of the chiromorphogenesis, mainly based on our own work, i.e. the first step of l-r symmetry breaking, as proven by our "Mechanogenetics", before the start of zygotic gene expression, transfer of chirality information to the cell-fate determining stage, and the expression of nodal at the blastula stage. The Nodal signalling pathway is a common mechanism in vertebrates' chiromorphogenesis in later development. Studies on snails, especially Lymnaea (L.) stagnalis, shall give important insights into the molecular basis of chiromorphogenesis not only in Lophotrochozoa but in vertebrates as well.

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Structure and Property Diversity of Chiral Helicene Oligomers

Saito

Shigeno

Yamaguchi

2015

Encyclopedia of Polymer Science and Technology

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alkylthio, and perfluoroalkyl groups. In addition, cyclization of helicene oligomers provides another method of obtaining diversity.A notable aspect in the diversity of helicene oligomers is that they can be connected to provide multidomain oligomers (Fig. 4). When two helicene oligomers are connected, they are referred to herein as homo-bidomain oligomers. Cyclic homo-bidomain oligomers are also conceivable. Hetero-multidomain oligomers can be obtained by connecting different structures of oligomers. Such manipulations provide a large diversity of structures.Because helicene can generate characteristic π−π interactions, helicene oligomers often form bimolecular, trimolecular, tetramolecular, and polymolecular aggregates in which homoaggregation and heteroaggregation can also occur. Such aggregates self-assemble to form fibrils, vesicles, liquid crystals, and surface monolayers. These noncovalent bonding interactions provide diversity of the structure of helicene oligmers. Diverse Properties of Helicene OligomersStructural diversity is directly related to diversity of properties, and the properties of a helicene oligomer can be varied by structural modifications. In addition, multidomain oligomers can be designed, in which properties A and B of each domain can be combined. Such compounds exhibit property A + B or even another property C, a result regarded as the "synthesis of a property or function." Aggregation and self-assembly of helicene oligomers further increase property diversity, which covers materials with a broad range of sizes from subnanometersized molecules through nano-and micrometer-sized molecular aggregates and molecular self-assemblies to macroscopic bulk materials. Helicene oligomers are sensitive to changes in the environment such as temperature, solvent, and concentration. Different properties appear in dilute solution, in concentrated Amidohelicene oligomers: (a) acylcic oligomers (P)-1 (n = 1−9) with dianiline spacer, cyclic oligomers (P)-2 (n = 1−10) with dianiline spacer, (b) acyclic oligomers (P)-3 (n = 1−9) with m-phenylene spacer, and acyclic reverse oligomers (P)-4 (n = 1−4). (c) Schematic representation of reversible change between helix dimer and random coils of (P)-3 and (P)-4. solution, in the crystalline state, in the amorphous state, on the solid surface, at the solid-liquid interface, in fiber assemblies, in liquid crystals, and in gels. Dynamic properties of helicene oligomers are also interesting, and structural changes are largely affected by the environment, providing a stimulus response or possible molecular switching materials. It is also noteworthy that the process of a structure change can produce unusual transient phenomena. Amidohelicene OligomersStudies on helicene oligomers were initiated with amide derivatives (Fig. 5a, top), in which the spacer has a bent shape and includes both hydrogen bonding donor and acceptor moieties (24). (P)-5,8-Helicenedicarboxylate was reacted with bis(2,6-dimethylanilino)cyclohexane to give a series of acyclic helicene oligomers 1 up t...

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Chiral blastomere arrangement dictates zygotic left–right asymmetry pathway in snails

Cited by 155 publications

References 27 publications

Far from solved: A perspective on what we know about early mechanisms of left–right asymmetry

Far from solved: A perspective on what we know about early mechanisms of left–right asymmetry

A twisting story: how a single gene twists a snail? Mechanogenetics

Structure and Property Diversity of Chiral Helicene Oligomers

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