Your search keyword '"Mario A. Mendieta-Serrano"' showing total 4 results

1. NADPH-Oxidase-derived reactive oxygen species are required for cytoskeletal organization, proper localization of E-cadherin and cell motility during zebrafish epiboly

Author

Denhi Schnabel, Francisco J. Mendez-Cruz, Luis Cárdenas, Mario A. Mendieta-Serrano, Laura Alvarez, Enrique Salas-Vidal, Hilda Lomelí, Mayra Antúnez-Mojica, and Juan A. Ruiz-Santiesteban

Subjects

0301 basic medicine, Embryo, Nonmammalian, Morphogenesis, Epiboly, Motility, Biochemistry, 03 medical and health sciences, 0302 clinical medicine, Cell Movement, Physiology (medical), Cell Adhesion, Animals, Blastoderm, Cell adhesion, Cytoskeleton, Zebrafish, NADPH oxidase, biology, Cadherin, Chemistry, NADPH Oxidases, Zebrafish Proteins, Cadherins, biology.organism_classification, Cell biology, 030104 developmental biology, embryonic structures, biology.protein, Reactive Oxygen Species, 030217 neurology & neurosurgery

Abstract

Cell movements are essential for morphogenesis during animal development. Epiboly is the first morphogenetic process in zebrafish in which cells move en masse to thin and spread the deep and enveloping cell layers of the blastoderm over the yolk cell. While epiboly has been shown to be controlled by complex molecular networks, the contribution of reactive oxygen species (ROS) to this process has not previously been studied. Here, we show that ROS are required for epiboly in zebrafish. Visualization of ROS in whole embryos revealed dynamic patterns during epiboly progression. Significantly, inhibition of NADPH oxidase activity leads to a decrease in ROS formation, delays epiboly, alters E-cadherin and cytoskeleton patterns and, by 24 h post-fertilization, decreases embryo survival, effects that are rescued by hydrogen peroxide treatment. Our findings suggest that a delicate ROS balance is required during early development and that disruption of that balance interferes with cell adhesion, leading to defective cell motility and epiboly progression.

Published

2019

2. Shaping the zebrafish myotome by intertissue friction and active stress

Author

Mario A. Mendieta-Serrano, Timothy E. Saunders, Sham Tlili, N. Verma, Yusuke Toyama, Jacques Prost, Xiang Teng, G. Weissbart, Jianmin Yin, Jean-François Rupprecht, and Mechanobiology Institute, National University of Singapore, Singapore 117411

Subjects

Embryo, Nonmammalian, Friction, [SDV]Life Sciences [q-bio], vertex models, Morphogenesis, Embryonic Development, Models, Biological, 03 medical and health sciences, 0302 clinical medicine, somitogenesis, Myotome, Live cell imaging, Somitogenesis, medicine, Paraxial mesoderm, Chevron (geology), Animals, Zebrafish, ComputingMilieux_MISCELLANEOUS, Cells, Cultured, 030304 developmental biology, Physics, 0303 health sciences, Multidisciplinary, biology, Muscle cell differentiation, Muscles, Biological Sciences, biology.organism_classification, organ morphogenesis, Cell biology, Biomechanical Phenomena, Biophysics and Computational Biology, medicine.anatomical_structure, Somites, PNAS Plus, tissue mechanics, Physical Sciences, Single-Cell Analysis, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Significance How do tissues self-organize to generate the complex organ shapes observed in vertebrates? Organ formation requires the integration of chemical and mechanical information, yet how this is achieved is poorly understood for most organs. Muscle compartments in zebrafish display a V shape, which is believed to be required for efficient swimming. We investigate how this structure emerges during zebrafish development, combining live imaging and quantitative analysis of cellular movements. We use theoretical modeling to understand how cell differentiation and mechanical interactions between tissues guide the emergence of a specific tissue morphology. Our work reveals how spatially modulating the mechanical environment around and within tissues can lead to complex organ shape formation., Organ formation is an inherently biophysical process, requiring large-scale tissue deformations. Yet, understanding how complex organ shape emerges during development remains a major challenge. During zebrafish embryogenesis, large muscle segments, called myotomes, acquire a characteristic chevron morphology, which is believed to aid swimming. Myotome shape can be altered by perturbing muscle cell differentiation or the interaction between myotomes and surrounding tissues during morphogenesis. To disentangle the mechanisms contributing to shape formation of the myotome, we combine single-cell resolution live imaging with quantitative image analysis and theoretical modeling. We find that, soon after segmentation from the presomitic mesoderm, the future myotome spreads across the underlying tissues. The mechanical coupling between the future myotome and the surrounding tissues appears to spatially vary, effectively resulting in spatially heterogeneous friction. Using a vertex model combined with experimental validation, we show that the interplay of tissue spreading and friction is sufficient to drive the initial phase of chevron shape formation. However, local anisotropic stresses, generated during muscle cell differentiation, are necessary to reach the acute angle of the chevron in wild-type embryos. Finally, tissue plasticity is required for formation and maintenance of the chevron shape, which is mediated by orientated cellular rearrangements. Our work sheds light on how a spatiotemporal sequence of local cellular events can have a nonlocal and irreversible mechanical impact at the tissue scale, leading to robust organ shaping.

Published

2019

3. Aryldihydronaphthalene-type lignans from Bursera fagaroides var. fagaroides and their antimitotic mechanism of action

Author

Alejandra León, Laura Alvarez, Mario A. Mendieta-Serrano, Enrique Salas-Vidal, Mayra Y. Antúnez Mojica, Silvia Marquina, Andrés M. Rojas-Sepúlveda, and María Luisa Villarreal

Subjects

0301 basic medicine, General Chemical Engineering, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Scopoletin, medicine, Burseraceae, biology, 010405 organic chemistry, Bursera, General Chemistry, Coumarin, biology.organism_classification, 0104 chemical sciences, 030104 developmental biology, Podophyllotoxin, chemistry, Biochemistry, Mechanism of action, Bursera fagaroides, visual_art, visual_art.visual_art_medium, Bark, medicine.symptom, medicine.drug

Abstract

Three new aryldihydronaphthalene-type lignans, namely, 7′,8′-dehydropodophyllotoxin (1); 7′,8′-dehydro acetylpodophyllotoxin (2); and 7′,8′-dehydro trans-p-cumaroylpodophyllotoxin (3), were isolated from the stem bark of Bursera fagaroides var. fagaroides (Burseraceae), together with six known lignans, podophyllotoxin (4), acetylpodophyllotoxin (5), 5′-desmethoxy-β-peltatin A methylether (6), acetylpicropodophyllotoxin (7), burseranin (8), and hinokinin (9). The coumarin scopoletin (10) was also isolated from this bark. The chemical structure of all these compounds was determined by spectroscopic analyses including 2D NMR. We demonstrated that compounds 1–3 show different degrees of cytotoxic activity against human nasopharyngeal (KB), colon (HF-6), breast (MCF-7) and prostate (PC-3) cancer cell lines, with IC50 values ranging from 1.49 to 1.0 × 10−5 μM. In vivo studies of the effect of these natural lignans on the cell cycle, cell migration and microtubule cytoskeleton of developing zebrafish embryos, demonstrated their antimitotic molecular activity by disturbing tubulin. This is the first report on the occurrence of aryldihydronaphthalene lignans in the genus Bursera of the Burseraceae family, as well as on the determination of their cytotoxic activity and mechanism of action.

Published

2016

4. Lignans from Bursera fagaroides Affect In Vivo Cell Behavior by Disturbing the Tubulin Cytoskeleton in Zebrafish Embryos

Author

Laura Alvarez, Mario A. Mendieta-Serrano, Enrique Salas-Vidal, Andrés M. Rojas-Sepúlveda, Mayra Antúnez-Mojica, Leticia González-Maya, and Silvia Marquina

Subjects

0301 basic medicine, animal structures, cell migration, Pharmaceutical Science, Epiboly, complex mixtures, Article, Analytical Chemistry, microtubules, lcsh:QD241-441, 03 medical and health sciences, F-actin, lcsh:Organic chemistry, Cell Movement, Tubulin, In vivo, Microtubule, Drug Discovery, Animals, cancer, Physical and Theoretical Chemistry, Cytoskeleton, Mitosis, Zebrafish, Molecular Structure, biology, Chemistry, Organic Chemistry, Bursera, lignans, Cell cycle, biology.organism_classification, Cell biology, 030104 developmental biology, Bursera fagaroides, epiboly, Chemistry (miscellaneous), embryonic structures, biology.protein, Molecular Medicine, cell cycle, podophyllotoxin-type lignans

Abstract

By using a zebrafish embryo model to guide the chromatographic fractionation of antimitotic secondary metabolites, seven podophyllotoxin-type lignans were isolated from a hydroalcoholic extract obtained from the steam bark of Bursera fagaroides. The compounds were identified as podophyllotoxin (1), &beta, peltatin-A-methylether (2), 5&prime, desmethoxy-&beta, peltatin-A-methylether (3), desmethoxy-yatein (4), desoxypodophyllotoxin (5), burseranin (6), and acetyl podophyllotoxin (7). The biological effects on mitosis, cell migration, and microtubule cytoskeleton remodeling of lignans 1&ndash, 7 were further evaluated in zebrafish embryos by whole-mount immunolocalization of the mitotic marker phospho-histone H3 and by a tubulin antibody. We found that lignans 1, 2, 4, and 7 induced mitotic arrest, delayed cell migration, and disrupted the microtubule cytoskeleton in zebrafish embryos. Furthermore, microtubule cytoskeleton destabilization was observed also in PC3 cells, except for 7. Therefore, these results demonstrate that the cytotoxic activity of 1, 2, and 4 is mediated by their microtubule-destabilizing activity. In general, the in vivo and in vitro models here used displayed equivalent mitotic effects, which allows us to conclude that the zebrafish model can be a fast and cheap in vivo model that can be used to identify antimitotic natural products through bioassay-guided fractionation.

Published

2018