Your search keyword '"Uzquiano, Ana"' showing total 8 results

1. Cell-type specific defects in PTEN-mutant cortical organoids converge on abnormal circuit activity.

Author

Pigoni, Martina, Uzquiano, Ana, Paulsen, Bruna, Kedaigle, Amanda J, Yang, Sung Min, Symvoulidis, Panagiotis, Adiconis, Xian, Velasco, Silvia, Sartore, Rafaela, Kim, Kwanho, Tucewicz, Ashley, Tropp, Sarah Yoshimi, Tsafou, Kalliopi, Jin, Xin, Barrett, Lindy, Chen, Fei, Boyden, Edward S, Regev, Aviv, Levin, Joshua Z, and Arlotta, Paola

Published

2023

2. Organoids as tools for fundamental discovery and translation—a Keystone Symposia report.

Author

Cable, Jennifer, Lutolf, Matthias P., Fu, Jianping, Park, Sunghee Estelle, Apostolou, Athanasia, Chen, Shuibing, Song, Cheng Jack, Spence, Jason R., Liberali, Prisca, Lancaster, Madeline, Meier, Anna B., Pek, Nicole Min Qian, Wells, James M., Capeling, Meghan M., Uzquiano, Ana, Musah, Samira, Huch, Meritxell, Gouti, Mina, Hombrink, Pleun, and Quadrato, Giorgia

Subjects

SYSTEMS biology, ORGANOIDS, HUMAN biology, DEVELOPMENTAL biology, MORPHOGENESIS, CELL culture

Abstract

Complex three‐dimensional in vitro organ‐like models, or organoids, offer a unique biological tool with distinct advantages over two‐dimensional cell culture systems, which can be too simplistic, and animal models, which can be too complex and may fail to recapitulate human physiology and pathology. Significant progress has been made in driving stem cells to differentiate into different organoid types, though several challenges remain. For example, many organoid models suffer from high heterogeneity, and it can be difficult to fully incorporate the complexity of in vivo tissue and organ development to faithfully reproduce human biology. Successfully addressing such limitations would increase the viability of organoids as models for drug development and preclinical testing. On April 3–6, 2022, experts in organoid development and biology convened at the Keystone Symposium "Organoids as Tools for Fundamental Discovery and Translation" to discuss recent advances and insights from this relatively new model system into human development and disease. [ABSTRACT FROM AUTHOR]

Published

2022

3. Autism genes converge on asynchronous development of shared neuron classes.

Author

Paulsen, Bruna, Velasco, Silvia, Kedaigle, Amanda J., Pigoni, Martina, Quadrato, Giorgia, Deo, Anthony J., Adiconis, Xian, Uzquiano, Ana, Sartore, Rafaela, Yang, Sung Min, Simmons, Sean K., Symvoulidis, Panagiotis, Kim, Kwanho, Tsafou, Kalliopi, Podury, Archana, Abbate, Catherine, Tucewicz, Ashley, Smith, Samantha N., Albanese, Alexandre, and Barrett, Lindy

Abstract

Genetic risk for autism spectrum disorder (ASD) is associated with hundreds of genes spanning a wide range of biological functions1–6. The alterations in the human brain resulting from mutations in these genes remain unclear. Furthermore, their phenotypic manifestation varies across individuals7,8. Here we used organoid models of the human cerebral cortex to identify cell-type-specific developmental abnormalities that result from haploinsufficiency in three ASD risk genes—SUV420H1 (also known as KMT5B), ARID1B and CHD8—in multiple cell lines from different donors, using single-cell RNA-sequencing (scRNA-seq) analysis of more than 745,000 cells and proteomic analysis of individual organoids, to identify phenotypic convergence. Each of the three mutations confers asynchronous development of two main cortical neuronal lineages—γ-aminobutyric-acid-releasing (GABAergic) neurons and deep-layer excitatory projection neurons—but acts through largely distinct molecular pathways. Although these phenotypes are consistent across cell lines, their expressivity is influenced by the individual genomic context, in a manner that is dependent on both the risk gene and the developmental defect. Calcium imaging in intact organoids shows that these early-stage developmental changes are followed by abnormal circuit activity. This research uncovers cell-type-specific neurodevelopmental abnormalities that are shared across ASD risk genes and are finely modulated by human genomic context, finding convergence in the neurobiological basis of how different risk genes contribute to ASD pathology.Haploinsufficiency in three genes associated with risk of autism spectrum disorder—KMT5B, ARID1B and CHD8—in cell lines from multiple donors results in cell-type-specific asynchronous development of GABAergic neurons and cortical deep-layer excitatory projection neurons. [ABSTRACT FROM AUTHOR]

Published

2022

4. The neuroanatomy of Eml1 knockout mice, a model of subcortical heterotopia.

Author

Collins, Stephan C., Uzquiano, Ana, Selloum, Mohammed, Wendling, Olivia, Gaborit, Marion, Osipenko, Maria, Birling, Marie‐Christine, Yalcin, Binnaz, and Francis, Fiona

Subjects

KNOCKOUT mice, CORPUS callosum, CEREBRAL cortex, NEUROANATOMY, MICROTUBULE-associated proteins, PROGENITOR cells, MICROTUBULES, AXONS

Abstract

The cerebral cortex is a highly organized structure responsible for advanced cognitive functions. Its development relies on a series of steps including neural progenitor cell proliferation, neuronal migration, axonal outgrowth and brain wiring. Disruption of these steps leads to cortical malformations, often associated with intellectual disability and epilepsy. We have generated a new resource to shed further light on subcortical heterotopia, a malformation characterized by abnormal neuronal position. We describe here the generation and characterization of a knockout (KO) mouse model for Eml1, a microtubule‐associated protein showing mutations in human ribbon‐like subcortical heterotopia. As previously reported for a spontaneous mouse mutant showing a mutation in Eml1, we observe severe cortical heterotopia in the KO. We also observe abnormal progenitor cells in early corticogenesis, likely to be the origin of the defects. EML1 KO mice on the C57BL/6N genetic background also appear to present a wider phenotype than the original mouse mutant, showing additional brain anomalies, such as corpus callosum abnormalities. We compare the anatomy of male and female mice and also study heterozygote animals. This new resource will help unravel roles for Eml1 in brain development and tissue architecture, as well as the mechanisms leading to severe subcortical heterotopia. [ABSTRACT FROM AUTHOR]

Published

2019

5. Rotatin' the phenotypes.

Author

Uzquiano, Ana and Francis, Fiona

Subjects

CHEMOKINE receptors, T helper cells, PHENOTYPES, CELL cycle, CELL populations, CARRIER proteins, CRANIOFACIAL abnormalities, CELL cycle proteins

Published

2019

6. Cortical progenitor biology: key features mediating proliferation versus differentiation.

Author

Uzquiano, Ana, Gladwyn‐Ng, Ivan, Nguyen, Laurent, Reiner, Orly, Götz, Magdalena, Matsuzaki, Fumio, and Francis, Fiona

Subjects

PROGENITOR cells, HIGHER nervous activity, CELL proliferation, CARRIER proteins, NEUROCHEMISTRY

Abstract

Abstract: The cerebral cortex is a highly organized structure whose development depends on diverse progenitor cell types, namely apical radial glia, intermediate progenitors, and basal radial glia cells, which are responsible for the production of the correct neuronal output. In recent years, these progenitor cell types have been deeply studied, particularly basal radial glia and their role in cortical expansion and gyrification. We review here a broad series of factors that regulate progenitor behavior and daughter cell fate. We first describe the different neuronal progenitor types, emphasizing the differences between lissencephalic and gyrencephalic species. We then review key factors shown to influence progenitor proliferation versus differentiation, discussing their roles in progenitor dynamics, neuronal production, and potentially brain size and complexity. Although spindle orientation has been considered a critical factor for mode of division and daughter cell output, we discuss other features that are emerging as crucial for these processes such as organelle and cell cycle dynamics. Additionally, we highlight the importance of adhesion molecules and the polarity complex for correct cortical development. Finally, we briefly discuss studies assessing progenitor multipotency and its possible contribution to the production of specific neuronal populations. This review hence summarizes recent aspects of cortical progenitor cell biology, and pinpoints emerging features critical for their behavior. [ABSTRACT FROM AUTHOR]

Published

2018

7. The assembly of developing motor neurons depends on an interplay between spontaneous activity, type II cadherins and gap junctions.

Author

Montague, Karli, Lowe, Andrew S., Uzquiano, Ana, Knüfer, Athene, Astick, Marc, Price, Stephen R., and Guthrie, Sarah

Subjects

MOTOR neurons, CADHERINS, GAP junctions (Cell biology), NUCLEOSYNTHESIS, CELL adhesion

Abstract

A core structural and functional motif of the vertebrate central nervous systemis discrete clusters of neurons or 'nuclei'. Yet the developmental mechanisms underlying this fundamental mode of organisation are largely unknown. We have previously shown that the assembly of motor neurons into nuclei depends on cadherin-mediated adhesion. Here, we demonstrate that the emergence of mature topography among motor nuclei involves a novel interplay between spontaneous activity, cadherin expression and gap junction communication. We report that nuclei display spontaneous calciumtransients, and that changes in the activity patterns coincide with the course of nucleogenesis. We also find that these activity patterns are disrupted by manipulating cadherin or gap junction expression. Furthermore, inhibition of activity disrupts nucleogenesis, suggesting that activity feeds back tomaintain integrityamong motor neurons within a nucleus. Our study suggests that a network of interactions between cadherins, gap junctions and spontaneous activity governs neuron assembly, presaging circuit formation. [ABSTRACT FROM AUTHOR]

Published

2017

8. Mutations in the Heterotopia Gene Eml1/EML1 Severely Disrupt the Formation of Primary Cilia.

Author

Uzquiano, Ana, Cifuentes-Diaz, Carmen, Jabali, Ammar, Romero, Delfina M., Houllier, Anne, Dingli, Florent, Maillard, Camille, Boland, Anne, Deleuze, Jean-François, Loew, Damarys, Mancini, Grazia M.S., Bahi-Buisson, Nadia, Ladewig, Julia, and Francis, Fiona

Abstract

Apical radial glia (aRGs) are predominant progenitors during corticogenesis. Perturbing their function leads to cortical malformations, including subcortical heterotopia (SH), characterized by the presence of neurons below the cortex. EML1 / Eml1 mutations lead to SH in patients, as well as to heterotopic cortex (HeCo) mutant mice. In HeCo mice, some aRGs are abnormally positioned away from the ventricular zone (VZ). Thus, unraveling EML1/Eml1 function will clarify mechanisms maintaining aRGs in the VZ. We pinpoint an unknown EML1/Eml1 function in primary cilium formation. In HeCo aRGs, cilia are shorter, less numerous, and often found aberrantly oriented within vesicles. Patient fibroblasts and human cortical progenitors show similar defects. EML1 interacts with RPGRIP1L, a ciliary protein, and RPGRIP1L mutations were revealed in a heterotopia patient. We also identify Golgi apparatus abnormalities in EML1 / Eml1 mutant cells, potentially upstream of the cilia phenotype. We thus reveal primary cilia mechanisms impacting aRG dynamics in physiological and pathological conditions. • Primary cilium formation is impaired in Eml1/EML1 mutant apical radial glia • EML1 interacts with RPGRIP1L, a primary cilium protein • RPGRIP1L shows gene variations in a patient with subcortical heterotopia • Altered Golgi apparatus in Eml1 mutant cells may perturb the Golgi-primary cilium axis Uzquiano et al. show that mutations in Eml1 / EML1 , found in mice and patients with subcortical heterotopia, impair primary cilia formation in apical progenitors. Perturbed anterograde trafficking from the Golgi apparatus seems likely to contribute to this ciliary phenotype. This work uncovers pathological mechanisms potentially triggering the formation of the heterotopia. [ABSTRACT FROM AUTHOR]

Published

2019