Your search keyword '"El-Yakoubi W"' showing total 14 results

1. Condensin dysfunction is a reproductive isolating barrier in mice.

Author

El Yakoubi W and Akera T

Subjects

Animals, Female, Mice classification, Mice genetics, Aneuploidy, Chromosome Segregation, Chromosomes, Mammalian genetics, Chromosomes, Mammalian metabolism, Hybridization, Genetic, Infertility, Female genetics, Meiosis genetics, Oocytes metabolism, Prophase genetics, Cell Nucleus genetics, Adenosine Triphosphatases metabolism, Centromere genetics, Centromere metabolism, DNA-Binding Proteins metabolism, Multiprotein Complexes metabolism

Abstract

Reproductive isolation occurs when the genomes of two populations accumulate genetic incompatibilities that prevent interbreeding 1,2 . Understanding of hybrid incompatibility at the cell biology level is limited, particularly in the case of hybrid female sterility 3 . Here we find that species divergence in condensin regulation and centromere organization between two mouse species, Mus musculus domesticus and Mus spretus, drives chromosome decondensation and mis-segregation in their F 1 hybrid oocytes, reducing female fertility. The decondensation in hybrid oocytes was especially prominent at pericentromeric major satellites, which are highly abundant at M. m. domesticus centromeres 4-6 , leading to species-specific chromosome mis-segregation and egg aneuploidy. Consistent with the condensation defects, a chromosome structure protein complex, condensin II 7,8 , was reduced on hybrid oocyte chromosomes. We find that the condensin II subunit NCAPG2 was specifically reduced in the nucleus in prophase and that overexpressing NCAPG2 rescued both the decondensation and egg aneuploidy phenotypes. In addition to the overall reduction in condensin II on chromosomes, major satellites further reduced condensin II levels locally, explaining why this region is particularly prone to decondensation. Together, this study provides cell biological insights into hybrid incompatibility in female meiosis and demonstrates that condensin misregulation and pericentromeric satellite expansion can establish a reproductive isolating barrier in mammals., (© 2023. This is a U.S. Government work and not under copyright protection in the US; foreign copyright protection may apply.)

Published

2023

2. Kinetochore individualization in meiosis I is required for centromeric cohesin removal in meiosis II.

Author

Gryaznova Y, Keating L, Touati SA, Cladière D, El Yakoubi W, Buffin E, and Wassmann K

Subjects

Animals, Cells, Cultured, Chromatids genetics, Chromatids metabolism, Female, Mice, Mice, Inbred C57BL, Oocytes metabolism, Cohesins, Cell Cycle Proteins metabolism, Chromosomal Proteins, Non-Histone metabolism, Kinetochores metabolism, Meiosis

Abstract

Partitioning of the genome in meiosis occurs through two highly specialized cell divisions, named meiosis I and meiosis II. Step-wise cohesin removal is required for chromosome segregation in meiosis I, and sister chromatid segregation in meiosis II. In meiosis I, mono-oriented sister kinetochores appear as fused together when examined by high-resolution confocal microscopy, whereas they are clearly separated in meiosis II, when attachments are bipolar. It has been proposed that bipolar tension applied by the spindle is responsible for the physical separation of sister kinetochores, removal of cohesin protection, and chromatid separation in meiosis II. We show here that this is not the case, and initial separation of sister kinetochores occurs already in anaphase I independently of bipolar spindle forces applied on sister kinetochores, in mouse oocytes. This kinetochore individualization depends on separase cleavage activity. Crucially, without kinetochore individualization in meiosis I, bivalents when present in meiosis II oocytes separate into chromosomes and not sister chromatids. This shows that whether centromeric cohesin is removed or not is determined by the kinetochore structure prior to meiosis II., (© 2021 The Authors. Published under the terms of the CC BY NC ND 4.0 license.)

Published

2021

3. Meiosis interrupted: the genetics of female infertility via meiotic failure.

Author

Biswas L, Tyc K, El Yakoubi W, Morgan K, Xing J, and Schindler K

Subjects

ATPases Associated with Diverse Cellular Activities, Aneuploidy, Aurora Kinase C genetics, Aurora Kinase C metabolism, Cell Cycle Proteins genetics, Chromosome Segregation, Female, Humans, Male, Meiosis, Nuclear Proteins, Pregnancy, Spermatozoa metabolism, Trans-Activators, Tubulin, Infertility, Female genetics

Abstract

Idiopathic or 'unexplained' infertility represents as many as 30% of infertility cases worldwide. Conception, implantation, and term delivery of developmentally healthy infants require chromosomally normal (euploid) eggs and sperm. The crux of euploid egg production is error-free meiosis. Pathologic genetic variants dysregulate meiotic processes that occur during prophase I, meiotic resumption, chromosome segregation, and in cell cycle regulation. This dysregulation can result in chromosomally abnormal (aneuploid) eggs. In turn, egg aneuploidy leads to a broad range of clinical infertility phenotypes, including primary ovarian insufficiency and early menopause, egg fertilization failure and embryonic developmental arrest, or recurrent pregnancy loss. Therefore, maternal genetic variants are emerging as infertility biomarkers, which could allow informed reproductive decision-making. Here, we select and deeply examine human genetic variants that likely cause dysregulation of critical meiotic processes in 14 female infertility-associated genes: SYCP3, SYCE1, TRIP13, PSMC3IP, DMC1, MCM8, MCM9, STAG3, PATL2, TUBB8, CEP120, AURKB, AURKC, andWEE2. We discuss the function of each gene in meiosis, explore genotype-phenotype relationships, and delineate the frequencies of infertility-associated variants.

Published

2021

4. Exome sequencing links CEP120 mutation to maternally derived aneuploid conception risk.

Author

Tyc KM, El Yakoubi W, Bag A, Landis J, Zhan Y, Treff NR, Scott RT, Tao X, Schindler K, and Xing J

Subjects

Adult, Animals, Blastocyst, Cell Cycle Proteins, Female, Humans, Mice, Middle Aged, Oocytes, Exome Sequencing, Young Adult, Aneuploidy, Exome

Abstract

Study Question: What are the genetic factors that increase the risk of aneuploid egg production?, Summary Answer: A non-synonymous variant rs2303720 within centrosomal protein 120 (CEP120) disrupts female meiosis in vitro in mouse., What Is Known Already: The production of aneuploid eggs, with an advanced maternal age as an established contributing factor, is the major cause of IVF failure, early miscarriage and developmental anomalies. The identity of maternal genetic variants contributing to egg aneuploidy irrespective of age is missing., Study Design, Size, Duration: Patients undergoing fertility treatment (n = 166) were deidentified and selected for whole-exome sequencing., Participants/materials, Setting, Methods: Patients self-identified their ethnic groups and their ages ranged from 22 to 49 years old. The study was performed using genomes from White, non-Hispanic patients divided into controls (97) and cases (69) according to the number of aneuploid blastocysts derived during each IVF procedure. Following a gene prioritization strategy, a mouse oocyte system was used to validate the functional significance of the discovered associated genetic variants., Main Results and the Role of Chance: Patients producing a high proportion of aneuploid blastocysts (considered aneuploid if they missed any of the 40 chromatids or had extra copies) were found to carry a higher mutational burden in genes functioning in cytoskeleton and microtubule pathways. Validation of the functional significance of a non-synonymous variant rs2303720 within Cep120 on mouse oocyte meiotic maturation revealed that ectopic expression of CEP120:p.Arg947His caused decreased spindle microtubule nucleation efficiency and increased incidence of aneuploidy., Limitations, Reasons for Caution: Functional validation was performed using the mouse oocyte system. Because spindle building pathways differ between mouse and human oocytes, the defects we observed upon ectopic expression of the Cep120 variant may alter mouse oocyte meiosis differently than human oocyte meiosis. Further studies using knock-in 'humanized' mouse models and in human oocytes will be needed to translate our findings to human system. Possible functional differences of the variant between ethnic groups also need to be investigated., Wider Implications of the Findings: Variants in centrosomal genes appear to be important contributors to the risk of maternal aneuploidy. Functional validation of these variants will eventually allow prescreening to select patients that have better chances to benefit from preimplantation genetic testing., Study Funding/competing Interest(s): This study was funded through R01-HD091331 to K.S. and J.X. and EMD Serono Grant for Fertility Innovation to N.R.T. N.R.T. is a shareholder and an employee of Genomic Prediction., Trial Registration Number: N/A., (© The Author(s) 2020. Published by Oxford University Press on behalf of European Society of Human Reproduction and Embryology. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2020

5. Genetic Interactions between the Aurora Kinases Reveal New Requirements for AURKB and AURKC during Oocyte Meiosis.

Author

Nguyen AL, Drutovic D, Vazquez BN, El Yakoubi W, Gentilello AS, Malumbres M, Solc P, and Schindler K

Subjects

Aneuploidy, Animals, Aurora Kinase A metabolism, Aurora Kinase B metabolism, Aurora Kinase C metabolism, Chromosome Segregation genetics, Female, Fertility genetics, Mice, Aurora Kinase A genetics, Aurora Kinase B genetics, Aurora Kinase C genetics, Meiosis, Oocytes metabolism

Abstract

Errors in chromosome segregation during female meiosis I occur frequently, and aneuploid embryos account for 1/3 of all miscarriages in humans [1]. Unlike mitotic cells that require two Aurora kinase (AURK) homologs to help prevent aneuploidy (AURKA and AURKB), mammalian germ cells also require a third (AURKC) [2, 3]. AURKA is the spindle-pole-associated homolog, and AURKB/C are the chromosome-localized homologs. In mitosis, AURKB has essential roles as the catalytic subunit of the chromosomal passenger complex (CPC), regulating chromosome alignment, kinetochore-microtubule attachments, cohesion, the spindle assembly checkpoint, and cytokinesis [4, 5]. In mouse oocyte meiosis, AURKC takes over as the predominant CPC kinase [6], although the requirement for AURKB remains elusive [7]. In the absence of AURKC, AURKB compensates, making defining potential non-overlapping functions difficult [6, 8]. To investigate the role(s) of AURKB and AURKC in oocytes, we analyzed oocyte-specific Aurkb and Aurkc single- and double-knockout (KO) mice. Surprisingly, we find that double KO female mice are fertile. We demonstrate that, in the absence of AURKC, AURKA localizes to chromosomes in a CPC-dependent manner. These data suggest that AURKC prevents AURKA from localizing to chromosomes by competing for CPC binding. This competition is important for adequate spindle length to support meiosis I. We also describe a unique requirement for AURKB to negatively regulate AURKC to prevent aneuploidy. Together, our work reveals oocyte-specific roles for the AURKs in regulating each other's localization and activity. This inter-kinase regulation is critical to support wild-type levels of fecundity in female mice., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

6. Tension-Induced Error Correction and Not Kinetochore Attachment Status Activates the SAC in an Aurora-B/C-Dependent Manner in Oocytes.

Author

Vallot A, Leontiou I, Cladière D, El Yakoubi W, Bolte S, Buffin E, and Wassmann K

Subjects

Animals, Cell Division drug effects, Cell Division physiology, Cysteine analogs & derivatives, Cysteine pharmacology, Female, Kinesins antagonists & inhibitors, Kinetochores drug effects, M Phase Cell Cycle Checkpoints drug effects, Mice, Oocytes drug effects, Paclitaxel pharmacology, Pyrimidines pharmacology, Thiones pharmacology, Tubulin Modulators pharmacology, Kinetochores physiology, M Phase Cell Cycle Checkpoints physiology, Meiosis physiology, Oocytes physiology

Abstract

Cell division with partitioning of the genetic material should take place only when paired chromosomes named bivalents (meiosis I) or sister chromatids (mitosis and meiosis II) are correctly attached to the bipolar spindle in a tension-generating manner. For this to happen, the spindle assembly checkpoint (SAC) checks whether unattached kinetochores are present, in which case anaphase onset is delayed to permit further establishment of attachments. Additionally, microtubules are stabilized when they are attached and under tension. In mitosis, attachments not under tension activate the so-named error correction pathway depending on Aurora B kinase substrate phosphorylation. This leads to microtubule detachments, which in turn activates the SAC [1-3]. Meiotic divisions in mammalian oocytes are highly error prone, with severe consequences for fertility and health of the offspring [4, 5]. Correct attachment of chromosomes in meiosis I leads to the generation of stretched bivalents, but-unlike mitosis-not to tension between sister kinetochores, which co-orient. Here, we set out to address whether reduction of tension applied by the spindle on bioriented bivalents activates error correction and, as a consequence, the SAC. Treatment of oocytes in late prometaphase I with Eg5 kinesin inhibitor affects spindle tension, but not attachments, as we show here using an optimized protocol for confocal imaging. After Eg5 inhibition, bivalents are correctly aligned but less stretched, and as a result, Aurora-B/C-dependent error correction with microtubule detachment takes place. This loss of attachments leads to SAC activation. Crucially, SAC activation itself does not require Aurora B/C kinase activity in oocytes., (Copyright © 2017 Elsevier Ltd. All rights reserved.)

Published

2018

7. Mps1 kinase-dependent Sgo2 centromere localisation mediates cohesin protection in mouse oocyte meiosis I.

Author

El Yakoubi W, Buffin E, Cladière D, Gryaznova Y, Berenguer I, Touati SA, Gómez R, Suja JA, van Deursen JM, and Wassmann K

Subjects

Animals, Cell Cycle Proteins analysis, Centromere ultrastructure, Mice, Oocytes metabolism, Oocytes ultrastructure, Phosphorylation, Protein Serine-Threonine Kinases metabolism, Cohesins, Cell Cycle Proteins metabolism, Centromere metabolism, Chromosomal Proteins, Non-Histone metabolism, Meiosis physiology, Oocytes cytology, Protein Serine-Threonine Kinases physiology

Abstract

A key feature of meiosis is the step-wise removal of cohesin, the protein complex holding sister chromatids together, first from arms in meiosis I and then from the centromere region in meiosis II. Centromeric cohesin is protected by Sgo2 from Separase-mediated cleavage, in order to maintain sister chromatids together until their separation in meiosis II. Failures in step-wise cohesin removal result in aneuploid gametes, preventing the generation of healthy embryos. Here, we report that kinase activities of Bub1 and Mps1 are required for Sgo2 localisation to the centromere region. Mps1 inhibitor-treated oocytes are defective in centromeric cohesin protection, whereas oocytes devoid of Bub1 kinase activity, which cannot phosphorylate H2A at T121, are not perturbed in cohesin protection as long as Mps1 is functional. Mps1 and Bub1 kinase activities localise Sgo2 in meiosis I preferentially to the centromere and pericentromere respectively, indicating that Sgo2 at the centromere is required for protection.In meiosis I centromeric cohesin is protected by Sgo2 from Separase-mediated cleavage ensuring that sister chromatids are kept together until their separation in meiosis II. Here the authors demonstrate that Bub1 and Mps1 kinase activities are required for Sgo2 localisation to the centromere region.

Published

2017

8. Meiotic Divisions: No Place for Gender Equality.

Author

El Yakoubi W and Wassmann K

Subjects

Age Factors, Aneuploidy, Animals, Female, Fertilization, Humans, Male, Pregnancy, Pregnancy Complications genetics, Pregnancy Outcome, Risk Factors, Sex Factors, Meiosis, Oocytes physiology, Oogenesis, Spermatogenesis, Spermatozoa physiology

Abstract

In multicellular organisms the fusion of two gametes with a haploid set of chromosomes leads to the formation of the zygote, the first cell of the embryo. Accurate execution of the meiotic cell division to generate a female and a male gamete is required for the generation of healthy offspring harboring the correct number of chromosomes. Unfortunately, meiosis is error prone. This has severe consequences for fertility and under certain circumstances, health of the offspring. In humans, female meiosis is extremely error prone. In this chapter we will compare male and female meiosis in humans to illustrate why and at which frequency errors occur, and describe how this affects pregnancy outcome and health of the individual. We will first introduce key notions of cell division in meiosis and how they differ from mitosis, followed by a detailed description of the events that are prone to errors during the meiotic divisions.

Published

2017

9. Direct regulation of siamois by VegT is required for axis formation in Xenopus embryo.

Author

Li HY, El Yakoubi W, and Shi DL

Subjects

Animals, Base Sequence, Blotting, Western, Body Patterning, Chromatin Immunoprecipitation, Embryo, Nonmammalian cytology, Homeodomain Proteins metabolism, Immunoenzyme Techniques, Molecular Sequence Data, Organizers, Embryonic, Promoter Regions, Genetic genetics, RNA, Messenger genetics, Real-Time Polymerase Chain Reaction, Reverse Transcriptase Polymerase Chain Reaction, Sequence Homology, Nucleic Acid, T-Box Domain Proteins genetics, Wnt Proteins genetics, Wnt Proteins metabolism, Xenopus laevis genetics, Xenopus laevis growth & development, Embryo, Nonmammalian metabolism, Gene Expression Regulation, Developmental, Homeodomain Proteins genetics, T-Box Domain Proteins metabolism, Xenopus Proteins genetics, Xenopus Proteins metabolism, Xenopus laevis metabolism

Abstract

The homeobox gene siamois is one of the earliest genes expressed in the Spemann organizer and plays a critical role in the formation of the dorsoventral axis. It is directly regulated by maternal Wnt signalling and functions as an essential zygotic intermediary between maternal factors and the formation of the Spemann organizer. The maternal T domain transcription factor VegT interacts with Wnt signalling and is also involved in the formation of the Spemann organizer. However, the molecular mechanism of this functional interaction is not fully understood. Here we show that VegT is required for siamois expression through direct binding to the T-box binding sites in the siamois promoter. Mutational analysis of each of the five consensus T-box binding sites suggests that the proximal site close to the transcription start site is essential for activation of siamois promoter by VegT, while individual mutation of the four distal sites has no effect. VegT and Wnt signalling also functionally interact and are mutually required for siamois expression. In particular, VegT synergizes with Tcf1, but not Tcf3 and Tcf4, to induce siamois expression, and this is independent of Tcf/Lef-binding sites or the proximal T-box binding site in the siamois promoter. We further extend previous observations by showing that VegT cooperates with maternal Wnt signalling in the formation of the dorsoventral axis. These results demonstrate that maternal VegT directly regulates siamois gene transcription in the formation of the Spemann organizer, and provide further insight into the mechanism underlying the functional interaction between VegT and Wnt signalling during development.

Published

2015

10. Hes4 controls proliferative properties of neural stem cells during retinal ontogenesis.

Author

El Yakoubi W, Borday C, Hamdache J, Parain K, Tran HT, Vleminckx K, Perron M, and Locker M

Subjects

Animals, Animals, Genetically Modified, Basic Helix-Loop-Helix Transcription Factors genetics, Cell Cycle physiology, Cell Differentiation physiology, Cell Growth Processes physiology, Female, Gene Expression Regulation, Developmental, Hedgehog Proteins metabolism, Immunohistochemistry, Male, Neural Stem Cells metabolism, Retina metabolism, Retinal Pigment Epithelium cytology, Retinal Pigment Epithelium embryology, Retinal Pigment Epithelium metabolism, Signal Transduction, Wnt Signaling Pathway, Xenopus Proteins genetics, Xenopus laevis, Basic Helix-Loop-Helix Transcription Factors biosynthesis, Neural Stem Cells cytology, Retina cytology, Retina embryology, Xenopus Proteins biosynthesis

Abstract

The retina of fish and amphibian contains genuine neural stem cells located at the most peripheral edge of the ciliary marginal zone (CMZ). However, their cell-of-origin as well as the mechanisms that sustain their maintenance during development are presently unknown. We identified Hes4 (previously named XHairy2), a gene encoding a bHLH-O transcriptional repressor, as a stem cell-specific marker of the Xenopus CMZ that is positively regulated by the canonical Wnt pathway and negatively by Hedgehog signaling. We found that during retinogenesis, Hes4 labels a small territory, located first at the pigmented epithelium (RPE)/neural retina (NR) border and later in the retinal margin, that likely gives rise to adult retinal stem cells. We next addressed whether Hes4 might impart this cell subpopulation with retinal stem cell features: inhibited RPE or NR differentiation programs, continuous proliferation, and slow cell cycle speed. We could indeed show that Hes4 overexpression cell autonomously prevents retinal precursor cells from commitment toward retinal fates and maintains them in a proliferative state. Besides, our data highlight for the first time that Hes4 may also constitute a crucial regulator of cell cycle kinetics. Hes4 gain of function indeed significantly slows down cell division, mainly through the lengthening of G1 phase. As a whole, we propose that Hes4 maintains particular stemness features in a cellular cohort dedicated to constitute the adult retinal stem cell pool, by keeping it in an undifferentiated and slowly proliferative state along embryonic retinogenesis., (Copyright © 2012 AlphaMed Press.)

Published

2012

11. A large scale screen for neural stem cell markers in Xenopus retina.

Author

Parain K, Mazurier N, Bronchain O, Borday C, Cabochette P, Chesneau A, Colozza G, El Yakoubi W, Hamdache J, Locker M, Gilchrist MJ, Pollet N, and Perron M

Subjects

Animals, Base Sequence, Biomarkers metabolism, In Situ Hybridization, Molecular Sequence Data, Neural Stem Cells metabolism, Polymerase Chain Reaction, Retina metabolism, Xenopus, Biomarkers analysis, Databases, Genetic, Gene Expression Profiling, Neural Stem Cells cytology, Retina cytology

Abstract

Neural stem cell research suffers from a lack of molecular markers to specifically assess stem or progenitor cell properties. The organization of the Xenopus ciliary marginal zone (CMZ) in the retina allows the spatial distinction of these two cell types: stem cells are confined to the most peripheral region, while progenitors are more central. Despite this clear advantage, very few genes specifically expressed in retinal stem cells have been discovered so far in this model. To gain insight into the molecular signature of these cells, we performed a large-scale expression screen in the Xenopus CMZ, establishing it as a model system for stem cell gene profiling. Eighteen genes expressed specifically in the CMZ stem cell compartment were retrieved and are discussed here. These encode various types of proteins, including factors associated with proliferation, mitotic spindle organization, DNA/RNA processing, and cell adhesion. In addition, the publication of this work in a special issue on Xenopus prompted us to give a more general illustration of the value of large-scale screens in this model species. Thus, beyond neural stem cell specific genes, we give a broader highlight of our screen outcome, describing in particular other retinal cell markers that we found. Finally, we present how these can all be easily retrieved through a novel module we developed in the web-based annotation tool XenMARK, and illustrate the potential of this powerful searchable database in the context of the retina., (Copyright © 2011 Wiley Periodicals, Inc.)

Published

2012

12. A bromodeoxyuridine (BrdU) based protocol for characterizing proliferating progenitors in Xenopus embryos.

Author

Auger H, Thuret R, El Yakoubi W, and Papalopulu N

Subjects

Animals, Antibodies chemistry, Cell Proliferation, DNA Replication, Fluorescent Antibody Technique, Indirect, In Situ Hybridization methods, Indicators and Reagents, Microinjections, Microtomy, S Phase Cell Cycle Checkpoints, Stem Cells metabolism, Bromodeoxyuridine chemistry, Embryo, Nonmammalian cytology, Stem Cells physiology, Xenopus physiology

Abstract

BrdU is a thymidine analog that is incorporated into DNA during the S-phase of the cell cycle. BrdU incorporation can be used to quantify the number of cells that are in S-phase in the time period that BrdU is available. Thus, BrdU incorporation is an essential method in the quantitative analysis of cell proliferation, during normal embryonic development or after experimental manipulation. It is a reliable and versatile method that can be easily combined with immunohistochemistry and in situ hybridization to relate cell proliferation with gene expression. BrdU incorporation has been used in all model organisms; here, we describe a protocol adapted for use in Xenopus embryos.

Published

2012

13. A decade of mammalian retinal stem cell research.

Author

Locker M, El Yakoubi W, Mazurier N, Dullin JP, and Perron M

Subjects

Animals, Ciliary Body cytology, History, 20th Century, History, 21st Century, Humans, Mammals, Neurons physiology, Adult Stem Cells physiology, Research history, Research Design, Retina cytology

Abstract

Ten years have now passed since the discovery of quiescent neural stem cells within the mammalian retina. Beside the fascinating aspect of stem cell biology in basic science, these cells have also offered hope for the treatment of incurable retinal diseases. The field has thus rapidly evolved, fluctuating between major advances and recurring doubts. In this review, we will retrace the efforts of scientists during this last decade to characterize these cells and to use them in regenerative medicine. We will also highlight advances made in animal models capable of stem cell-mediated retinal regeneration.

Published

2010

14. MafA transcription factor identifies the early ret-expressing sensory neurons.

Author

Lecoin L, Rocques N, El-Yakoubi W, Ben Achour S, Larcher M, Pouponnot C, and Eychène A

Subjects

Animals, Cell Differentiation genetics, Cell Lineage genetics, Cell Size, Ganglia, Spinal cytology, Gene Expression Regulation, Developmental genetics, Genetic Markers genetics, Maf Transcription Factors, Large biosynthesis, Mechanoreceptors cytology, Mice, Mice, Inbred C57BL, Mice, Knockout, Mice, Transgenic, Mutagenesis, Insertional, Neural Crest cytology, Proto-Oncogene Proteins c-ret genetics, Sensory Receptor Cells cytology, Ganglia, Spinal embryology, Maf Transcription Factors, Large genetics, Mechanoreceptors metabolism, Neural Crest embryology, Proto-Oncogene Proteins c-ret biosynthesis, Sensory Receptor Cells metabolism

Abstract

Dorsal root ganglia proceed from the coalescence of cell bodies of sensory neurons, which have migrated dorsoventrally from the delaminating neural crest. They are composed of different neuronal subtypes with specific sensory functions, including nociception, thermal sensation, proprioception, and mechanosensation. In contrast to proprioceptors and thermonociceptors, little is known about the molecular mechanisms governing the early commitment and later differentiation into mechanosensitive neurons. This is mainly due to the absence of specific molecular markers for this particular cell type. Using knockout mice, we identified the bZIP transcription factor MafA as the first specific marker of a subpopulation of "early c-ret" positive neurons characterized by medium-to-large diameters. This marker will allow further functional characterization of these neurons.

Published

2010