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Your search keyword '"Baizabal, José-Manuel"' showing total 19 results
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19 results on '"Baizabal, José-Manuel"'

2. PRDM16 co-operates with LHX2 to shape the human brain.

Author

Suresh, Varun, Bhattacharya, Bidisha, Tshuva, Rami, Danan Gotthold, Miri, Olender, Tsviya, Bose, Mahima, Pradhan, Saurabh, Zeev, Bruria, Smith, Richard, Tole, Shubha, Galande, Sanjeev, Harwell, Corey, Baizabal, José-Manuel, and Reiner, Orly

Subjects
1p36 deletion syndrome, LHX2, PRDM16, brain development, cerebral organoids, human disease model
Abstract

PRDM16 is a dynamic transcriptional regulator of various stem cell niches, including adipocytic, hematopoietic, cardiac progenitors, and neural stem cells. PRDM16 has been suggested to contribute to 1p36 deletion syndrome, one of the most prevalent subtelomeric microdeletion syndromes. We report a patient with a de novo nonsense mutation in the PRDM16 coding sequence, accompanied by lissencephaly and microcephaly features. Human stem cells were genetically modified to mimic this mutation, generating cortical organoids that exhibited altered cell cycle dynamics. RNA sequencing of cortical organoids at day 32 unveiled changes in cell adhesion and WNT-signaling pathways. ChIP-seq of PRDM16 identified binding sites in postmortem human fetal cortex, indicating the conservation of PRDM16 binding to developmental genes in mice and humans, potentially at enhancer sites. A shared motif between PRDM16 and LHX2 was identified and further examined through comparison with LHX2 ChIP-seq data from mice. These results suggested a collaborative partnership between PRDM16 and LHX2 in regulating a common set of genes and pathways in cortical radial glia cells, possibly via their synergistic involvement in cortical development.

Published
2024

8. Transcriptional regulation of MGE progenitor proliferation by PRDM16 controls cortical GABAergic interneuron production

Author

Turrero García, Miguel, primary, Baizabal, José-Manuel, additional, Tran, Diana N., additional, Peixoto, Rui, additional, Wang, Wengang, additional, Xie, Yajun, additional, Adam, Manal A., additional, English, Lauren A., additional, Reid, Christopher M., additional, Brito, Salvador I., additional, Booker, Matthew A., additional, Tolstorukov, Michael Y., additional, and Harwell, Corey C., additional

Published
2020
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9. Transcriptional regulation of MGE progenitor proliferation by PRDM16 controls cortical GABAergic interneuron production

Author

García, Miguel Turrero, primary, Baizabal, José-Manuel, additional, Tran, Diana, additional, Peixoto, Rui, additional, Wang, Wengang, additional, Xie, Yajun, additional, Adam, Manal A., additional, Brito, Salvador, additional, Booker, Matthew A., additional, Tolstorukov, Michael Y., additional, and Harwell, Corey C., additional

Published
2019
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10. Transcriptional regulation of MGE progenitor proliferation by PRDM16 controls cortical GABAergic interneuron production.

Author

García, Miguel Turrero, Baizabal, José-Manuel, Tran, Diana N., Rui Peixoto, Wengang Wang, Yajun Xie, Adam, Manal A., English, Lauren A., Reid, Christopher M., Brito, Salvador I., Booker, Matthew A., Tolstorukov, Michael Y., and Harwell, Corey C.

Subjects
*NEURONAL differentiation, *GENE regulatory networks, *GENE expression, *TELENCEPHALON, *INDUSTRIAL capacity, *INTERNEURONS, *NEUROGLIA
Abstract

The mammalian cortex is populated by neurons derived from neural progenitors located throughout the embryonic telencephalon. Excitatory neurons are derived from the dorsal telencephalon, whereas inhibitory interneurons are generated in its ventral portion. The transcriptional regulator PRDM16 is expressed by radial glia, neural progenitors present in both regions; however, its mechanisms of action are still not fully understood. It is unclear whether PRDM16 plays a similar role in neurogenesis in both dorsal and ventral progenitor lineages and, if so, whether it regulates common or unique networks of genes. Here, we show that Prdm16 expression in mouse medial ganglionic eminence (MGE) progenitors is required for maintaining their proliferative capacity and for the production of proper numbers of forebrain GABAergic interneurons. PRDM16 binds to cis-regulatory elements and represses the expression of region-specific neuronal differentiation genes, thereby controlling the timing of neuronal maturation. PRDM16 regulates convergent developmental gene expression programs in the cortex and MGE, which utilize both common and region-specific sets of genes to control the proliferative capacity of neural progenitors, ensuring the generation of correct numbers of cortical neurons. [ABSTRACT FROM AUTHOR]

Published
2020
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12. Neural-specific Sox2 input and differential Gli-binding affinity provide context and positional information in Shh-directed neural patterning

Author

Peterson, Kevin A., primary, Nishi, Yuichi, additional, Ma, Wenxiu, additional, Vedenko, Anastasia, additional, Shokri, Leila, additional, Zhang, Xiaoxiao, additional, McFarlane, Matthew, additional, Baizabal, José-Manuel, additional, Junker, Jan Philipp, additional, van Oudenaarden, Alexander, additional, Mikkelsen, Tarjei, additional, Bernstein, Bradley E., additional, Bailey, Timothy L., additional, Bulyk, Martha L., additional, Wong, Wing H., additional, and McMahon, Andrew P., additional

Published
2012
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16. "Transcriptional Regulation of human NMNAT2: Insights from 3D Genome Sequencing and Bioinformatics".

Author

Chang YC, Yang S, Cho M, Nho K, Baizabal JM, and Lu HC

Abstract

Nicotinamide mononucleotide adenylyl transferases 2 (NMNAT2) is a crucial nicotinamide adenine dinucleotide (NAD)-synthesizing enzyme essential for neuronal health. In the Religious Orders Study/Memory and Aging Project (ROSMAP), human brain levels of NMNAT2 mRNA positively correlated with cognitive capabilities in older adults. NMNAT2 mRNA abundance is significantly reduced following various insults or proteinopathies. To elucidate the transcriptional regulation of NMNAT2, we employed circular chromosome conformation capture followed by high-throughput sequencing (4C-seq) to identify potential NMNAT2 enhancer and silencer regions by determining genomic regions interacting with the NMNAT2 promoter in human SH-SY5Y cells. We discovered distinct NMNAT2 promoter interactomes in undifferentiated versus neuron-like SH-SY5Y cells. Utilizing bioinformatics analyses, we identified putative transcriptional factors and NMNAT2-associated genes. Notably, the mRNA levels of many of these genes showed a significant correlation with NMNAT2 mRNA levels in ∼400 single-nuclei RNA-seq datasets from ROSMAP. Additionally, using CRISPR-Cas9 strategies, we confirmed the requirement of two specific genomic regions within the interactomes and four transcription factors in regulating NMNAT2 transcription. In summary, our study identifies genomic loci containing NMNAT2 regulatory elements and predicts associated genes and transcription factors through computational analyses.

Published
2024
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17. PRDM16 co-operates with LHX2 to shape the human brain.

Author

Suresh V, Bhattacharya B, Tshuva RY, Danan Gotthold M, Olender T, Bose M, Pradhan SJ, Zeev BB, Smith RS, Tole S, Galande S, Harwell CC, Baizabal JM, and Reiner O

Abstract

PRDM16 is a dynamic transcriptional regulator of various stem cell niches, including adipocytic, hematopoietic, cardiac progenitors, and neural stem cells. PRDM16 has been suggested to contribute to 1p36 deletion syndrome, one of the most prevalent subtelomeric microdeletion syndromes. We report a patient with a de novo nonsense mutation in the PRDM16 coding sequence, accompanied by lissencephaly and microcephaly features. Human stem cells were genetically modified to mimic this mutation, generating cortical organoids that exhibited altered cell cycle dynamics. RNA sequencing of cortical organoids at day 32 unveiled changes in cell adhesion and WNT-signaling pathways. ChIP-seq of PRDM16 identified binding sites in postmortem human fetal cortex, indicating the conservation of PRDM16 binding to developmental genes in mice and humans, potentially at enhancer sites. A shared motif between PRDM16 and LHX2 was identified and further examined through comparison with LHX2 ChIP-seq data from mice. These results suggested a collaborative partnership between PRDM16 and LHX2 in regulating a common set of genes and pathways in cortical radial glia cells, possibly via their synergistic involvement in cortical development., (© The Author(s) 2024. Published by Oxford University Press. All rights reserved.)

Published
2024
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18. PRDM16 co-operates with LHX2 to shape the human brain.

Author

Suresh V, Bhattacharya B, Tshuva RY, Danan Gotthold M, Olender T, Bose M, Pradhan SJ, Ben Zeev B, Smith RS, Tole S, Galande S, Harwell C, Baizabal JM, and Reiner O

Abstract

PRDM16 is a dynamic transcriptional regulator of various stem cell niches, including adipocytic, hematopoietic, cardiac progenitors, and neural stem cells. PRDM16 has been suggested to contribute to 1p36 deletion syndrome, one of the most prevalent subtelomeric microdeletion syndromes. We report a patient with a de novo nonsense mutation in the PRDM16 coding sequence, accompanied by lissencephaly and microcephaly features. Human stem cells were genetically modified to mimic this mutation, generating cortical organoids that exhibited altered cell cycle dynamics. RNA sequencing of cortical organoids at day 32 unveiled changes in cell adhesion and WNT-signaling pathways. ChIP-seq of PRDM16 identified binding sites in postmortem human fetal cortex, indicating the conservation of PRDM16 binding to developmental genes in mice and humans, potentially at enhancer sites. A shared motif between PRDM16 and LHX2 was identified and further examined through comparison with LHX2 ChIP-seq data from mice. These results suggested a collaborative partnership between PRDM16 and LHX2 in regulating a common set of genes and pathways in cortical radial glia cells, possibly via their synergistic involvement in cortical development.

Published
2023
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19. Growth factor deprivation induces an alternative non-apoptotic death mechanism that is inhibited by Bcl2 in cells derived from neural precursor cells.

Author

Cárdenas-Aguayo Mdel C, Santa-Olalla J, Baizabal JM, Salgado LM, and Covarrubias L

Subjects
Adenine pharmacology, Amino Acid Chloromethyl Ketones pharmacology, Animals, Apoptosis drug effects, Apoptosis physiology, Apoptosis Regulatory Proteins, Autophagy drug effects, Autophagy physiology, Beclin-1, Caspase Inhibitors, Cell Death drug effects, Cell Death physiology, Cell Differentiation drug effects, Cell Differentiation physiology, Cell Survival drug effects, Cell Survival physiology, Chromones pharmacology, Cycloheximide pharmacology, Enzyme Inhibitors pharmacology, Epidermal Growth Factor pharmacology, Fibroblast Growth Factor 2 deficiency, Fibroblast Growth Factor 2 pharmacology, Gene Expression Regulation genetics, Glial Fibrillary Acidic Protein analysis, Green Fluorescent Proteins, Immunohistochemistry, Intermediate Filament Proteins analysis, Luminescent Proteins genetics, Mesencephalon cytology, Mice, Microscopy, Electron, Morpholines pharmacology, Nerve Tissue Proteins analysis, Nestin, Neurons drug effects, Neurons physiology, Proteins genetics, Proto-Oncogene Proteins genetics, Proto-Oncogene Proteins c-bcl-2, Stem Cells drug effects, Stem Cells physiology, Transformation, Genetic genetics, Tubulin analysis, Vacuoles drug effects, Vacuoles physiology, Vacuoles ultrastructure, Adenine analogs & derivatives, Fibroblast Growth Factor 2 physiology, Neurons cytology, Proto-Oncogene Proteins physiology, Stem Cells cytology
Abstract

Although apoptosis has been considered the typical mechanism for physiological cell death, presently alternative mechanisms need to be considered. We previously showed that fibroblast growth factor-2 (FGF2) could act as a survival factor for neural precursor cells. To study the death mechanism activated by the absence of this growth factor, we followed the changes in cell morphology and determined cell viability by staining with several dyes after FGF2 removal from mesencephalic neural-progenitor-cell cultures. The changes observed did not correspond to those associated with apoptosis. After 48 h in the absence of FGF2, cells began to develop vacuoles in their cytoplasm, a phenotype that became very obvious 3-5 days later. Double-membrane vacuoles containing cell debris were observed. Vacuolated cells did not stain with either ethidium bromide or trypan Blue, and did not show chromatin condensations. Nonetheless, during the course of culture, vacuolated cells formed aggregates with highly condensed chromatin and detached from the plate. Neural progenitor cells grown in the presence of FGF2 did not display any of those characteristics. The vacuolated phenotype could be reversed by the addition of FGF2. Typical autophagy inhibitors such as 3-MA and LY294002 inhibited vacuole development, whereas a broad-spectrum caspase inhibitor did not. Interestingly, Bcl-2 overexpression retarded vacuole development. In conclusion, we identified a death autophagy-like mechanism activated by the lack of a specific survival factor that can be inhibited by Bcl2. We propose that anti-apoptotic Bcl2 family members are key molecules controlling death activation independently of the cell degeneration mechanism used.

Published
2003
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