Your search keyword '"Brotons, Maria"' showing total 5 results

1. Importin 13-dependent axon diameter growth regulates conduction speeds along myelinated CNS axons.

Author

Bin JM, Suminaite D, Benito-Kwiecinski SK, Kegel L, Rubio-Brotons M, Early JJ, Soong D, Livesey MR, Poole RJ, and Lyons DA

Subjects

Animals, Myelin Sheath physiology, Central Nervous System, Neurons, Zebrafish, Axons physiology

Abstract

Axon diameter influences the conduction properties of myelinated axons, both directly, and indirectly through effects on myelin. However, we have limited understanding of mechanisms controlling axon diameter growth in the central nervous system, preventing systematic dissection of how manipulating diameter affects myelination and conduction along individual axons. Here we establish zebrafish to study axon diameter. We find that importin 13b is required for axon diameter growth, but does not affect cell body size or axon length. Using neuron-specific ipo13b mutants, we assess how reduced axon diameter affects myelination and conduction, and find no changes to myelin thickness, precision of action potential propagation, or ability to sustain high frequency firing. However, increases in conduction speed that occur along single myelinated axons with development are tightly linked to their growth in diameter. This suggests that axon diameter growth is a major driver of increases in conduction speeds along myelinated axons over time., (© 2024. The Author(s).)

Published

2024

2. Morphometric analysis of developing zebrafish embryos allows predicting teratogenicity modes of action in higher vertebrates.

Author

Jarque, Sergio, Rubio-Brotons, Maria, Ibarra, Jone, Ordoñez, Víctor, Dyballa, Sylvia, Miñana, Rafael, and Terriente, Javier

Subjects

*ZEBRA danio embryos, *MANDIBLE, *VERTEBRATES, *EMBRYOS, *VALPROIC acid, *ANIMAL models in research

Abstract

• Zebrafish embryos are able to predict teratogenicity in mammals at similar rates than rodents. • Phenotype evaluation proves that most teratogenic phenotypes in zebrafish manifest together. • Teratogenic index ≥3 and EC50 ≤1000 μM are good limits to differentiate teratogens from non-teratogens in zebrafish. • Statistical analysis reveal correlation between phenotype and potential modes of action. The early identification of teratogens in humans and animals is mandatory for drug discovery and development. Zebrafish has emerged as an alternative model to traditional preclinical models for predicting teratogenicity and other potential chemical-induced toxicity hazards. To prove its predictivity, we exposed zebrafish embryos from 0 to 96 h post fertilization to a battery of 31 compounds classified as teratogens or non-teratogens in mammals. The teratogenicity score was based on the measurement of 16 phenotypical parameters, namely heart edema, pigmentation, body length, eye size, yolk size, yolk sac edema, otic vesicle defects, otoliths defects, body axis defects, developmental delay, tail bending, scoliosis, lateral fins absence, hatching ratio, lower jaw malformations and tissue necrosis. Among the 31 compounds, 20 were detected as teratogens and 11 as non-teratogens, resulting in 94.44 % sensitivity, 90.91 % specificity and 87.10 % accuracy compared to rodents. These percentages decreased slightly when referred to humans, with 87.50 % sensitivity, 81.82 % specificity and 74.19 % accuracy, but allowed an increase in the prediction levels reported by rodents for the same compounds. Positive compounds showed a high correlation among teratogenic parameters, pointing out at general developmental delay as major cause to explain the physiological/morphological malformations. A more detailed analysis based on deviations from main trends revealed potential specific modes of action for some compounds such as retinoic acid, DEAB, ochratoxin A, haloperidol, warfarin, valproic acid, acetaminophen, dasatinib, imatinib, dexamethasone, 6-aminonicotinamide and bisphenol A. The high degree of predictivity and the possibility of applying mechanistic approaches makes zebrafish a powerful model for screening teratogenicity. [ABSTRACT FROM AUTHOR]

Published

2020

3. Comparison of Zebrafish Larvae and hiPSC Cardiomyocytes for Predicting Drug-Induced Cardiotoxicity in Humans.

Author

Dyballa, Sylvia, Miñana, Rafael, Rubio-Brotons, Maria, Cornet, Carles, Pederzani, Tiziana, Escaramis, Georgia, Garcia-Serna, Ricard, Mestres, Jordi, and Terriente, Javier

Subjects

PLURIPOTENT stem cells, ZEBRA danio, ZEBRA danio embryos, INDUCED pluripotent stem cells, BRACHYDANIO, CARDIOTOXICITY, LARVAE, BLOOD flow

Abstract

Cardiovascular drug toxicity is responsible for 17% of drug withdrawals in clinical phases, half of post-marketed drug withdrawals and remains an important adverse effect of several marketed drugs. Early assessment of drug-induced cardiovascular toxicity is mandatory and typically done in cellular systems and mammals. Current in vitro screening methods allow high-throughput but are biologically reductionist. The use of mammal models, which allow a better translatability for predicting clinical outputs, is low-throughput, highly expensive, and ethically controversial. Given the analogies between the human and the zebrafish cardiovascular systems, we propose the use of zebrafish larvae during early drug discovery phases as a balanced model between biological translatability and screening throughput for addressing potential liabilities. To this end, we have developed a high-throughput screening platform that enables fully automatized in vivo image acquisition and analysis to extract a plethora of relevant cardiovascular parameters: heart rate, arrhythmia, AV blockage, ejection fraction, and blood flow, among others. We have used this platform to address the predictive power of zebrafish larvae for detecting potential cardiovascular liabilities in humans. We tested a chemical library of 92 compounds with known clinical cardiotoxicity profiles. The cross-comparison with clinical data and data acquired from human induced pluripotent stem cell cardiomyocytes calcium imaging showed that zebrafish larvae allow a more reliable prediction of cardiotoxicity than cellular systems. Interestingly, our analysis with zebrafish yields similar predictive performance as previous validation meta-studies performed with dogs, the standard regulatory preclinical model for predicting cardiotoxic liabilities prior to clinical phases. [ABSTRACT FROM AUTHOR]

Published

2019

4. Multiplex Analysis Platform for Endocrine Disruption Prediction Using Zebrafish.

Author

Jarque, Sergio, Ibarra, Jone, Rubio-Brotons, Maria, García-Fernández, Jessica, and Terriente, Javier

Subjects

FISHES, ENDOCRINE disruptors, BIOLOGICAL tags, AROMATASE, TESTOSTERONE

Abstract

Small fish are an excellent experimental model to screen endocrine-disrupting compounds, but current fish-based assays to detect endocrine disruption have not been standardized yet, meaning that there is not consensus on endpoints and biomarkers to be measured. Moreover, exposure conditions may vary depending on the species used as the experimental model and the endocrine pathway evaluated. At present, a battery of a wide range of assays is usually needed for the complete assessment of endocrine activities. With the aim of providing a simple, robust, and fast assay to assess endocrine-disrupting potencies for the three major endocrine axes, i.e., estrogens, androgens, and thyroid, we propose the use of a panel of eight gene expression biomarkers in zebrafish larvae. This includes brain aromatase (cyp19a1b) and vitellogenin 1 (vtg1) for estrogens, cytosolic sulfotransferase 2 family 2 (sult2st3) and cytochrome P450 2k22 (cyp2k22) for androgens, and thyroid peroxidase (tpo), transthyretin (ttr), thyroid receptor α (trα), and iodothyronine deiodinase 2 (dio2) for thyroid metabolism. All of them were selected according to their responses after exposure to the natural ligands 17β-estradiol, testosterone, and 3,3′,5-triiodo-L-thyronine (T3), respectively, and subsequently validated using compounds reported as endocrine disruptors in previous studies. Cross-talk effects were also evaluated for all compounds. [ABSTRACT FROM AUTHOR]

Published

2019

5. Oligodendrocyte Neurofascin Independently Regulates Both Myelin Targeting and Sheath Growth in the CNS.

Author

Klingseisen, Anna, Ristoiu, Ana-Maria, Kegel, Linde, Sherman, Diane L., Rubio-Brotons, Maria, Almeida, Rafael G., Koudelka, Sigrid, Benito-Kwiecinski, Silvia K., Poole, Richard J., Brophy, Peter J., and Lyons, David A.

Subjects

*OLIGODENDROGLIA, *MYELIN sheath, *CENTRAL nervous system, *SCHWANN cells, *NEUROGLIA, *GENETIC testing

Abstract

Selection of the correct targets for myelination and regulation of myelin sheath growth are essential for central nervous system (CNS) formation and function. Through a genetic screen in zebrafish and complementary analyses in mice, we find that loss of oligodendrocyte Neurofascin leads to mistargeting of myelin to cell bodies, without affecting targeting to axons. In addition, loss of Neurofascin reduces CNS myelination by impairing myelin sheath growth. Time-lapse imaging reveals that the distinct myelinating processes of individual oligodendrocytes can engage in target selection and sheath growth at the same time and that Neurofascin concomitantly regulates targeting and growth. Disruption to Caspr, the neuronal binding partner of oligodendrocyte Neurofascin, also impairs myelin sheath growth, likely reflecting its association in an adhesion complex at the axon-glial interface with Neurofascin. Caspr does not, however, affect myelin targeting, further indicating that Neurofascin independently regulates distinct aspects of CNS myelination by individual oligodendrocytes in vivo. • Single oligodendrocytes coordinate myelin targeting and growth at the same time • Oligodendrocyte Neurofascin prevents myelination of cell bodies • Oligodendrocyte Neurofascin promotes myelin sheath growth • The neuronal binding partner of Neurofascin, Caspr, promotes myelin sheath growth How individual oligodendrocytes coordinate the targeting and growth of myelin is unknown. Klingseisen et al. find that oligodendrocytes employ Neurofascin to prevent myelin mistargeting to cell bodies and also to support the stable growth of sheaths along axons in the CNS of both zebrafish and mice. [ABSTRACT FROM AUTHOR]

Published

2019