Your search keyword '"Nikolopoulou, Evanthia"' showing total 6 results

1. Association of embryonic inositol status with susceptibility to neural tube defects, metabolite profile, and maternal inositol intake.

Author

Leung KY, Weston E, De Castro SCP, Nikolopoulou E, Sudiwala S, Savery D, Eaton S, Copp AJ, and Greene NDE

Subjects

Animals, Female, Mice, Pregnancy, Embryo, Mammalian metabolism, Maternal Nutritional Physiological Phenomena, Metabolome, Folic Acid metabolism, Inositol metabolism, Inositol pharmacology, Neural Tube Defects metabolism, Neural Tube Defects prevention & control

Abstract

Maternal nutrition contributes to gene-environment interactions that influence susceptibility to common congenital anomalies such as neural tube defects (NTDs). Supplemental myo-inositol (MI) can prevent NTDs in some mouse models and shows potential for prevention of human NTDs. We investigated effects of maternal MI intake on embryonic MI status and metabolism in curly tail mice, which are genetically predisposed to NTDs that are inositol-responsive but folic acid resistant. Dietary MI deficiency caused diminished MI in maternal plasma and embryos, showing that de novo synthesis is insufficient to maintain MI levels in either adult or embryonic mice. Under normal maternal dietary conditions, curly tail embryos that developed cranial NTDs had significantly lower MI content than unaffected embryos, revealing an association between diminished MI status and failure of cranial neurulation. Expression of inositol-3-phosphate synthase 1, required for inositol biosynthesis, was less abundant in the cranial neural tube than at other axial levels. Supplemental MI or d-chiro-inositol (DCI) have previously been found to prevent NTDs in curly tail embryos. Here, we investigated the metabolic effects of MI and DCI treatments by mass spectrometry-based metabolome analysis. Among inositol-responsive metabolites, we noted a disproportionate effect on nucleotides, especially purines. We also found altered proportions of 5-methyltetrahydrolate and tetrahydrofolate in MI-treated embryos suggesting altered folate metabolism. Treatment with nucleotides or the one-carbon donor formate has also been found to prevent NTDs in curly tail embryos. Together, these findings suggest that the protective effect of inositol may be mediated through the enhanced supply of nucleotides during neural tube closure., (© 2024 The Author(s). The FASEB Journal published by Wiley Periodicals LLC on behalf of Federation of American Societies for Experimental Biology.)

Published

2024

2. A non-coding insertional mutation of Grhl2 causes gene over-expression and multiple structural anomalies including cleft palate, spina bifida and encephalocele.

Author

Crane-Smith Z, De Castro SCP, Nikolopoulou E, Wolujewicz P, Smedley D, Lei Y, Mather E, Santos C, Hopkinson M, Pitsillides AA, Finnell RH, Ross ME, Copp AJ, and Greene NDE

Subjects

Animals, Humans, Mice, Encephalocele genetics, Mutation, Abnormalities, Multiple genetics, Cleft Lip genetics, Cleft Palate genetics, Neural Tube Defects genetics, Spinal Dysraphism genetics

Abstract

Orofacial clefts, including cleft lip and palate (CL/P) and neural tube defects (NTDs) are among the most common congenital anomalies, but knowledge of the genetic basis of these conditions remains incomplete. The extent to which genetic risk factors are shared between CL/P, NTDs and related anomalies is also unclear. While identification of causative genes has largely focused on coding and loss of function mutations, it is hypothesized that regulatory mutations account for a portion of the unidentified heritability. We found that excess expression of Grainyhead-like 2 (Grhl2) causes not only spinal NTDs in Axial defects (Axd) mice but also multiple additional defects affecting the cranial region. These include orofacial clefts comprising midline cleft lip and palate and abnormalities of the craniofacial bones and frontal and/or basal encephalocele, in which brain tissue herniates through the cranium or into the nasal cavity. To investigate the causative mutation in the Grhl2Axd strain, whole genome sequencing identified an approximately 4 kb LTR retrotransposon insertion that disrupts the non-coding regulatory region, lying approximately 300 base pairs upstream of the 5' UTR. This insertion also lies within a predicted long non-coding RNA, oriented on the reverse strand, which like Grhl2 is over-expressed in Axd (Grhl2Axd) homozygous mutant embryos. Initial analysis of the GRHL2 upstream region in individuals with NTDs or cleft palate revealed rare or novel variants in a small number of cases. We hypothesize that mutations affecting the regulation of GRHL2 may contribute to craniofacial anomalies and NTDs in humans., (© The Author(s) 2023. Published by Oxford University Press.)

Published

2023

3. Overexpression of Grainyhead-like 3 causes spina bifida and interacts genetically with mutant alleles of Grhl2 and Vangl2 in mice.

Author

De Castro SCP, Gustavsson P, Marshall AR, Gordon WM, Galea G, Nikolopoulou E, Savery D, Rolo A, Stanier P, Andersen B, Copp AJ, and Greene NDE

Subjects

Alleles, Animals, Animals, Genetically Modified genetics, Disease Models, Animal, Embryonic Development genetics, Gene Expression Regulation, Developmental genetics, Humans, Loss of Function Mutation, Mice, Neural Tube Defects pathology, Protein Multimerization genetics, Spinal Dysraphism pathology, DNA-Binding Proteins genetics, Nerve Tissue Proteins genetics, Neural Tube Defects genetics, Spinal Dysraphism genetics, Transcription Factors genetics

Abstract

The genetic basis of human neural tube defects (NTDs), such as anencephaly and spina bifida (SB), is complex and heterogeneous. Grainyhead-like genes represent candidates for involvement in NTDs based on the presence of SB and exencephaly in mice carrying loss-of-function alleles of Grhl2 or Grhl3. We found that reinstatement of Grhl3 expression, by bacterial artificial chromosome (BAC)-mediated transgenesis, prevents SB in Grhl3-null embryos, as in the Grhl3 hypomorphic curly tail strain. Notably, however, further increase in expression of Grhl3 causes highly penetrant SB. Grhl3 overexpression recapitulates the spinal NTD phenotype of loss-of-function embryos, although the underlying mechanism differs. However, it does not phenocopy other defects of Grhl3-null embryos such as abnormal axial curvature, cranial NTDs (exencephaly) or skin barrier defects, the latter being rescued by the Grhl3-transgene. Grhl2 and Grhl3 can form homodimers and heterodimers, suggesting a possible model in which defects arising from overexpression of Grhl3 result from sequestration of Grhl2 in heterodimers, mimicking Grhl2 loss of function. This hypothesis predicts that increased abundance of Grhl2 would have an ameliorating effect in Grhl3 overexpressing embryo. Instead, we observed a striking additive genetic interaction between Grhl2 and Grhl3 gain-of-function alleles. Severe SB arose in embryos in which both genes were expressed at moderately elevated levels that individually do not cause NTDs. Furthermore, moderate Grhl3 overexpression also interacted with the Vangl2Lp allele to cause SB, demonstrating genetic interaction with the planar cell polarity signalling pathway that is implicated in mouse and human NTDs.

Published

2018

4. Neural tube closure: cellular, molecular and biomechanical mechanisms.

Author

Nikolopoulou E, Galea GL, Rolo A, Greene ND, and Copp AJ

Subjects

Animals, Body Patterning, Cell Movement, Cell Polarity, Embryonic Development, Fibronectins metabolism, Humans, Laminin metabolism, Morphogenesis, Proteoglycans metabolism, Risk Factors, Signal Transduction, Stress, Mechanical, Transcription Factors metabolism, Neural Tube embryology, Neural Tube Defects embryology, Neurulation

Abstract

Neural tube closure has been studied for many decades, across a range of vertebrates, as a paradigm of embryonic morphogenesis. Neurulation is of particular interest in view of the severe congenital malformations - 'neural tube defects' - that result when closure fails. The process of neural tube closure is complex and involves cellular events such as convergent extension, apical constriction and interkinetic nuclear migration, as well as precise molecular control via the non-canonical Wnt/planar cell polarity pathway, Shh/BMP signalling, and the transcription factors Grhl2/3, Pax3, Cdx2 and Zic2. More recently, biomechanical inputs into neural tube morphogenesis have also been identified. Here, we review these cellular, molecular and biomechanical mechanisms involved in neural tube closure, based on studies of various vertebrate species, focusing on the most recent advances in the field., (© 2017. Published by The Company of Biologists Ltd.)

Published

2017

5. Claudins are essential for cell shape changes and convergent extension movements during neural tube closure

Author

Baumholtz, Amanda I., Simard, Annie, Nikolopoulou, Evanthia, Oosenbrug, Marcus, Collins, Michelle M., Piontek, Anna, Krause, Gerd, Piontek, Jörg, Greene, Nicholas D.E., and Ryan, Aimee K.

Subjects

Convergent extension, Apical constriction, Claudin, Tight junctions, Neural tube defects

Abstract

During neural tube closure, regulated changes at the level of individual cells are translated into large-scale morphogenetic movements to facilitate conversion of the flat neural plate into a closed tube. Throughout this process, the integrity of the neural epithelium is maintained via cell interactions through intercellular junctions, including apical tight junctions. Members of the claudin family of tight junction proteins regulate paracellular permeability, apical-basal cell polarity and link the tight junction to the actin cytoskeleton. Here, we show that claudins are essential for neural tube closure: the simultaneous removal of Cldn3, −4 and −8 from tight junctions caused folate-resistant open neural tube defects. Their removal did not affect cell type differentiation, neural ectoderm patterning nor overall apical-basal polarity. However, apical accumulation of Vangl2, RhoA, and pMLC were reduced, and Par3 and Cdc42 were mislocalized at the apical cell surface. Our data showed that claudins act upstream of planar cell polarity and RhoA/ROCK signaling to regulate cell intercalation and actin-myosin contraction, which are required for convergent extension and apical constriction during neural tube closure, respectively.

Published

2017

6. Biomechanical coupling facilitates spinal neural tube closure in mouse embryos.

Author

Galea, Gabriel L., Young-June Cho, Galea, Gauden, Molè, Matteo A., Rolo, Ana, Savery, Dawn, Moulding, Dale, Culshaw, Lucy H., Nikolopoulou, Evanthia, Greene, Nicholas D. E., and Copp, Andrew J.

Subjects

NEURAL tube defects, SPINAL cord tumors, SPINA bifida, NEUROLOGIC examination, ABLATION techniques

Abstract

Neural tube (NT) formation in the spinal region of the mammalian embryo involves a wave of "zippering" that passes down the elongating spinal axis, uniting the neural fold tips in the dorsal midline. Failure of this closure process leads to open spina bifida, a common cause of severe neurologic disability in humans. Here, we combined a tissue-level strain-mapping workflow with laser ablation of live-imaged mouse embryos to investigate the biomechanics of mammalian spinal closure. Ablation of the zippering point at the embryonic dorsal midline causes far-reaching, rapid separation of the elevating neural folds. Strain analysis revealed tissue expansion around the zippering point after ablation, but predominant tissue constriction in the caudal and ventral neural plate zone. This zone is biomechanically coupled to the zippering point by a supracellular F-actin network, which includes an actin cable running along the neural fold tips. Pharmacologic inhibition of F-actin or laser ablation of the cable causes neural fold separation. At the most advanced somite stages, when completion of spinal closure is imminent, the cable forms a continuous ring around the neuropore, and simultaneously, a new caudal-to-rostral zippering point arises. Laser ablation of this new closure initiation point causes neural fold separation, demonstrating its biomechanical activity. Failure of spinal closure in pre-spina bifida Zic2Ku mutant embryos is associated with altered tissue biomechanics, as indicated by greater neuropore widening after ablation. Thus, this study identifies biomechanical coupling of the entire region of active spinal neurulation in the mouse embryo as a prerequisite for successful NT closure. [ABSTRACT FROM AUTHOR]

Published

2017