N. N. Luchinskaya scite author profile

Gastrulation in amphibian embryos is a composition of several differently located morphogenetic movements which are perfectly coordinated with each other both in space and time. We hypothesize that this coordination is mediated by biomechanical interactions between different parts of a gastrulating embryo based upon the tendency of each part to hyper-restore the value of its mechanical stress (see Beloussov and Grabovsky, 2006). The entire process of gastrulation in amphibian embryos is considered as a chain of these mutually coupled reactions, which are largely dependent upon the geometry of a given embryo part. We divide gastrulation into several partly overlapped steps, give a theoretical interpretation for each of them, formulate the experiments for testing our interpretation and describe the experimental results which confirm our point of view. Among the predicted experimental results are: inhibition of radial cell intercalation by relaxation of tensile stresses at the blastula stage; inversion of convergent intercalation movements by relaxation of circumferential stresses at the early gastrula stage; stress-promoted reorientation of axial rudiments, and others. We also show that gastrulation is going on under a more or less constant average value of tensile stresses which may play a role as rate-limiting factors. A macromorphological biomechanical approach developed in this paper is regarded as complementary to exploring the molecular machinery of gastrulation.

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The protein encoded by the germ plasm RNA Germes associates with dynein light chains and functions in Xenopus germline development

Berekelya

Mikryukov

Luchinskaya

et al. 2007

Differentiation

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Xenopus Germes encodes a novel germ plasm-associated transcript

Berekelya¹,

Ponomarev²,

Luchinskaya³

et al. 2003

Gene Expression Patterns

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Overexpression of Camello, a Member of a Novel Protein Family, Reduces Blastomere Adhesion and Inhibits Gastrulation in Xenopus laevis

Popsueva

Luchinskaya

Ludwig

et al. 2001

Developmental Biology

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Vertebrate gastrulation involves complex coordinated movements of cells and cell layers to establish the axial structures and the general body plan. Adhesion molecules and the components of extracellular matrix were shown to be involved in this process. However, other participating molecules and detailed mechanisms of the control of gastrulation movements remain largely unknown. Here, we describe a novel Xenopus gene camello (Xcml) which is expressed in the suprablastoporal zone of gastrulating embryos. Injection of Xcml RNA into dorsovegetal blastomeres retards or inhibits gastrulation movements. Database searches revealed a family of mammalian mRNAs encoding polypeptides highly similar to Xcml protein. Characteristic features of the camello family include the presence of the central hydrophobic domain and the N-acetyltransferase consensus motifs in the C-terminal part, as well as functional similarity to Xcml revealed by overexpression studies in Xenopus embryos. Xcml expression results in the decrease of cell adhesion as demonstrated by the microscopic analysis and the blastomere aggregation assay. Cell fractionation and confocal microscopy data suggest that Xcml protein is localized in the secretory pathway. We propose that Xcml may fine tune the gastrulation movements by modifying the cell surface and possibly extracellular matrix proteins passing through the secretory pathway.

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N. N. Luchinskaya

Gastrulation in amphibian embryos, regarded as a succession of biomechanical feedback events

The protein encoded by the germ plasm RNA Germes associates with dynein light chains and functions in Xenopus germline development

Xenopus Germes encodes a novel germ plasm-associated transcript

Overexpression of Camello, a Member of a Novel Protein Family, Reduces Blastomere Adhesion and Inhibits Gastrulation in Xenopus laevis

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