Your search keyword '"Maynard TM"' showing total 51 results

1. Out of Line or Altered States? Neural Progenitors as a Target in a Polygenic Neurodevelopmental Disorder.

Author

Rukh S, Meechan DW, Maynard TM, and Lamantia AS

Subjects

Male, Humans, Cerebral Cortex metabolism, Cell Lineage physiology, Signal Transduction, Neurogenesis physiology, Cell Differentiation physiology, Neurons metabolism, Neurodevelopmental Disorders genetics, Neurodevelopmental Disorders metabolism

Abstract

The genesis of a mature complement of neurons is thought to require, at least in part, precursor cell lineages in which neural progenitors have distinct identities recognized by exclusive expression of one or a few molecular markers. Nevertheless, limited progenitor types distinguished by specific markers and lineal progression through such subclasses cannot easily yield the magnitude of neuronal diversity in most regions of the nervous system. The late Verne Caviness, to whom this edition of Developmental Neuroscience is dedicated, recognized this mismatch. In his pioneering work on the histogenesis of the cerebral cortex, he acknowledged the additional flexibility required to generate multiple classes of cortical projection and interneurons. This flexibility may be accomplished by establishing cell states in which levels rather than binary expression or repression of individual genes vary across each progenitor's shared transcriptome. Such states may reflect local, stochastic signaling via soluble factors or coincidence of cell surface ligand/receptor pairs in subsets of neighboring progenitors. This probabilistic, rather than determined, signaling could modify transcription levels via multiple pathways within an apparently uniform population of progenitors. Progenitor states, therefore, rather than lineal relationships between types may underlie the generation of neuronal diversity in most regions of the nervous system. Moreover, mechanisms that influence variation required for flexible progenitor states may be targets for pathological changes in a broad range of neurodevelopmental disorders, especially those with polygenic origins., (© 2023 The Author(s). Published by S. Karger AG, Basel.)

Published

2024

2. Ranbp1 modulates morphogenesis of the craniofacial midline in mouse models of 22q11.2 deletion syndrome.

Author

Paronett EM, Bryan CA, Maynard ME, Goroff JA, Meechan DW, LaMantia AS, and Maynard TM

Subjects

Animals, Mice, Morphogenesis genetics, Disease Models, Animal, Phenotype, Neural Crest, DiGeorge Syndrome genetics

Abstract

Facial dysmorphology is a hallmark of 22q11.2 deletion syndrome (22q11DS). Nearly all affected individuals have facial features characteristic of the syndrome: a vertically long face with broad nasal bridge, narrow palpebral fissures and mild micrognathia, sometimes accompanied by facial skeletal and oropharyngeal anomalies. Despite the frequency of craniofacial dysmorphology due to 22q11.2 deletion, there is still incomplete understanding of the contribution of individual 22q11 genes to craniofacial and oropharyngeal development. We asked whether homozygous or heterozygous loss of function of single 22q11 genes compromises craniofacial and/or oropharyngeal morphogenesis related to these 22q11DS phenotypes. We found that Ranbp1, a 22q11DS gene that mediates nucleocytoplasmic protein trafficking, is a dosage-dependent modulator of craniofacial development. Ranbp1-/- embryos have variably penetrant facial phenotypes, including altered facial morphology and cleft palate. This 22q11DS-related dysmorphology is particularly evident in the midline of the facial skeleton, as evidenced by a robustly quantifiable dysmorphology of the vomer, an unpaired facial midline bone. 22q11DS-related oropharyngeal phenotypes reflect Ranbp1 function in both the cranial neural crest and cranial ectoderm based upon tissue-selective Ranbp1 deletion. Analyses of genetic interaction show that Ranbp1 mutation disrupts BMP signaling-dependent midline gene expression and BMP-mediated craniofacial and cranial skeletal morphogenesis. Finally, midline defects that parallel those in Ranbp1 mutant mice are observed at similar frequencies in the LgDel 22q112DS mouse model. Apparently, Ranbp1 is a modulator of craniofacial development, and in the context of broader 22q11 deletion, Ranbp1 mutant phenotypes mirror key aspects of 22q11DS midline facial anomalies., (© The Author(s) 2023. Published by Oxford University Press.)

Published

2023

3. Identity, lineage and fates of a temporally distinct progenitor population in the embryonic olfactory epithelium.

Author

Paronett EM, Bryan CA, Maynard TM, and LaMantia AS

Subjects

Mice, Animals, Epithelial Cells, Olfactory Mucosa, Olfactory Receptor Neurons

Abstract

We defined a temporally and transcriptionally divergent precursor cohort in the medial olfactory epithelium (OE) shortly after it differentiates as a distinct tissue at mid-gestation in the mouse. This temporally distinct population of Ascl1+ cells in the dorsomedial OE is segregated from Meis1+/Pax7+ progenitors in the lateral OE, and does not appear to be generated by Pax7+ lateral OE precursors. The medial Ascl1+ precursors do not yield a substantial number of early-generated ORNs. Instead, they first generate additional proliferative precursors as well as a distinct population of frontonasal mesenchymal cells associated with the migratory mass that surrounds the nascent olfactory nerve. Parallel to these in vivo distinctions, isolated medial versus lateral OE precursors in vitro retain distinct proliferative capacities and modes of division that reflect their in vivo identities. At later fetal stages, these early dorsomedial Ascl1+ precursors cells generate spatially restricted subsets of ORNs as well as other non-neuronal cell classes. Accordingly, the initial compliment of ORNs and other OE cell types is derived from at least two distinct early precursor populations: lateral Meis1/Pax7+ precursors that generate primarily early ORNs, and a temporally, spatially, and transcriptionally distinct subset of medial Ascl1+ precursors that initially generate additional OE progenitors and apparent migratory mass cells before yielding a subset of ORNs and likely supporting cell classes., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

4. Selective disruption of trigeminal sensory neurogenesis and differentiation in a mouse model of 22q11.2 deletion syndrome.

Author

Karpinski BA, Maynard TM, Bryan CA, Yitsege G, Horvath A, Lee NH, Moody SA, and LaMantia AS

Subjects

Animals, Cell Differentiation, Humans, Mice, Neural Crest, Neurogenesis, Sensory Receptor Cells, DiGeorge Syndrome

Abstract

22q11.2 Deletion Syndrome (22q11DS) is a neurodevelopmental disorder associated with cranial nerve anomalies and disordered oropharyngeal function, including pediatric dysphagia. Using the LgDel 22q11DS mouse model, we investigated whether sensory neuron differentiation in the trigeminal ganglion (CNgV), which is essential for normal orofacial function, is disrupted. We did not detect changes in cranial placode cell translocation or neural crest migration at early stages of LgDel CNgV development. However, as the ganglion coalesces, proportions of placode-derived LgDel CNgV cells increase relative to neural crest cells. In addition, local aggregation of placode-derived cells increases and aggregation of neural crest-derived cells decreases in LgDel CNgV. This change in cell-cell relationships was accompanied by altered proliferation of placode-derived cells at embryonic day (E)9.5, and premature neurogenesis from neural crest-derived precursors, reflected by an increased frequency of asymmetric neurogenic divisions for neural crest-derived precursors by E10.5. These early differences in LgDel CNgV genesis prefigure changes in sensory neuron differentiation and gene expression by postnatal day 8, when early signs of cranial nerve dysfunction associated with pediatric dysphagia are observed in LgDel mice. Apparently, 22q11 deletion destabilizes CNgV sensory neuron genesis and differentiation by increasing variability in cell-cell interaction, proliferation and sensory neuron differentiation. This early developmental divergence and its consequences may contribute to oropharyngeal dysfunction, including suckling, feeding and swallowing disruptions at birth, and additional orofacial sensory/motor deficits throughout life., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2022

5. Aberrant early growth of individual trigeminal sensory and motor axons in a series of mouse genetic models of 22q11.2 deletion syndrome.

Author

Motahari Z, Maynard TM, Popratiloff A, Moody SA, and LaMantia AS

Subjects

Animals, Axons metabolism, Axons pathology, Chromosome Deletion, DiGeorge Syndrome physiopathology, Disease Models, Animal, Humans, Mice, Mice, Knockout, Motor Activity genetics, Phenotype, Rhombencephalon growth & development, Rhombencephalon physiopathology, Trigeminal Nerve pathology, Aldehyde Oxidoreductases genetics, DiGeorge Syndrome genetics, Nuclear Proteins genetics, T-Box Domain Proteins genetics

Abstract

We identified divergent modes of initial axon growth that prefigure disrupted differentiation of the trigeminal nerve (CN V), a cranial nerve essential for suckling, feeding and swallowing (S/F/S), a key innate behavior compromised in multiple genetic developmental disorders including DiGeorge/22q11.2 Deletion Syndrome (22q11.2 DS). We combined rapid in vivo labeling of single CN V axons in LgDel+/- mouse embryos, a genomically accurate 22q11.2DS model, and 3D imaging to identify and quantify phenotypes that could not be resolved using existing methods. We assessed these phenotypes in three 22q11.2-related genotypes to determine whether individual CN V motor and sensory axons wander, branch and sprout aberrantly in register with altered anterior-posterior hindbrain patterning and gross morphological disruption of CN V seen in LgDel+/-. In the additional 22q11.2-related genotypes: Tbx1+/-, Ranbp1-/-, Ranbp1+/- and LgDel+/-:Raldh2+/-; axon phenotypes are seen when hindbrain patterning and CN V gross morphology is altered, but not when it is normal or restored toward WT. This disordered growth of CN V sensory and motor axons, whose appropriate targeting is critical for optimal S/F/S, may be an early, critical determinant of imprecise innervation leading to inefficient oropharyngeal function associated with 22q11.2 deletion from birth onward., (© The Author(s) 2020. Published by Oxford University Press. All rights reserved. For Permissions, please email: journals.permissions@oup.com.)

Published

2020

6. Variations in maternal vitamin A intake modifies phenotypes in a mouse model of 22q11.2 deletion syndrome.

Author

Yitsege G, Stokes BA, Sabatino JA, Sugrue KF, Banyai G, Paronett EM, Karpinski BA, Maynard TM, LaMantia AS, and Zohn IE

Subjects

Animals, Deglutition, Disease Models, Animal, Mice, Phenotype, Vitamin A, DiGeorge Syndrome

Abstract

Background: Vitamin A regulates patterning of the pharyngeal arches, cranial nerves, and hindbrain that are essential for feeding and swallowing. In the LgDel mouse model of 22q11.2 deletion syndrome (22q11DS), morphogenesis of multiple structures involved in feeding and swallowing are dysmorphic. We asked whether changes in maternal dietary Vitamin A intake can modify cranial nerve, hindbrain and pharyngeal arch artery development in the embryo as well as lung pathology that can be a sign of aspiration dysphagia in LgDel pups., Methods: Three defined amounts of vitamin A (4, 10, and 16 IU/g) were provided in the maternal diet. Cranial nerve, hindbrain and pharyngeal arch artery development was evaluated in embryos and inflammation in the lungs of pups to determine the impact of altering maternal diet on these phenotypes., Results: Reduced maternal vitamin A intake improved whereas increased intake exacerbated lung inflammation in LgDel pups. These changes were accompanied by increased incidence and/or severity of pharyngeal arch artery and cranial nerve V (CN V) abnormalities in LgDel embryos as well as altered expression of Cyp26b1 in the hindbrain., Conclusions: Our studies demonstrate that variations in maternal vitamin A intake can influence the incidence and severity of phenotypes in a mouse model 22q11.2 deletion syndrome., (© 2020 The Authors. Birth Defects Research published by Wiley Periodicals, LLC.)

Published

2020

7. Suckling, Feeding, and Swallowing: Behaviors, Circuits, and Targets for Neurodevelopmental Pathology.

Author

Maynard TM, Zohn IE, Moody SA, and LaMantia AS

Subjects

Animals, Behavior physiology, Deglutition physiology, Deglutition Disorders physiopathology, Humans, Pharynx physiology, Animals, Suckling physiology, Deglutition Disorders pathology, Nerve Net physiology, Pharynx pathology

Abstract

All mammals must suckle and swallow at birth, and subsequently chew and swallow solid foods, for optimal growth and health. These initially innate behaviors depend critically upon coordinated development of the mouth, tongue, pharynx, and larynx as well as the cranial nerves that control these structures. Disrupted suckling, feeding, and swallowing from birth onward-perinatal dysphagia-is often associated with several neurodevelopmental disorders that subsequently alter complex behaviors. Apparently, a broad range of neurodevelopmental pathologic mechanisms also target oropharyngeal and cranial nerve differentiation. These aberrant mechanisms, including altered patterning, progenitor specification, and neurite growth, prefigure dysphagia and may then compromise circuits for additional behavioral capacities. Thus, perinatal dysphagia may be an early indicator of disrupted genetic and developmental programs that compromise neural circuits and yield a broad range of behavioral deficits in neurodevelopmental disorders.

Published

2020

8. Transcriptional dysregulation in developing trigeminal sensory neurons in the LgDel mouse model of DiGeorge 22q11.2 deletion syndrome.

Author

Maynard TM, Horvath A, Bernot JP, Karpinski BA, Tavares ALP, Shah A, Zheng Q, Spurr L, Olender J, Moody SA, Fraser CM, LaMantia AS, and Lee NH

Published

2020

9. Transcriptional dysregulation in developing trigeminal sensory neurons in the LgDel mouse model of DiGeorge 22q11.2 deletion syndrome.

Author

Maynard TM, Horvath A, Bernot JP, Karpinski BA, Tavares ALP, Shah A, Zheng Q, Spurr L, Olender J, Moody SA, Fraser CM, LaMantia AS, and Lee NH

Subjects

Animals, DiGeorge Syndrome genetics, Embryo, Mammalian metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Sensory Receptor Cells metabolism, Trigeminal Nerve metabolism, DiGeorge Syndrome pathology, Disease Models, Animal, Embryo, Mammalian pathology, Gene Expression Regulation, Sensory Receptor Cells pathology, Transcriptome, Trigeminal Nerve pathology

Abstract

LgDel mice, which model the heterozygous deletion of genes at human chromosome 22q11.2 associated with DiGeorge/22q11.2 deletion syndrome (22q11DS), have cranial nerve and craniofacial dysfunction as well as disrupted suckling, feeding and swallowing, similar to key 22q11DS phenotypes. Divergent trigeminal nerve (CN V) differentiation and altered trigeminal ganglion (CNgV) cellular composition prefigure these disruptions in LgDel embryos. We therefore asked whether a distinct transcriptional state in a specific population of early differentiating LgDel cranial sensory neurons, those in CNgV, a major source of innervation for appropriate oropharyngeal function, underlies this departure from typical development. LgDel versus wild-type (WT) CNgV transcriptomes differ significantly at E10.5 just after the ganglion has coalesced. Some changes parallel altered proportions of cranial placode versus cranial neural crest-derived CNgV cells. Others are consistent with a shift in anterior-posterior patterning associated with divergent LgDel cranial nerve differentiation. The most robust quantitative distinction, however, is statistically verifiable increased variability of expression levels for most of the over 17 000 genes expressed in common in LgDel versus WT CNgV. Thus, quantitative expression changes of functionally relevant genes and increased stochastic variation across the entire CNgV transcriptome at the onset of CN V differentiation prefigure subsequent disruption of cranial nerve differentiation and oropharyngeal function in LgDel mice., (© The Author(s) 2020. Published by Oxford University Press.)

Published

2020

10. Mitochondrial Dysfunction Leads to Cortical Under-Connectivity and Cognitive Impairment.

Author

Fernandez A, Meechan DW, Karpinski BA, Paronett EM, Bryan CA, Rutz HL, Radin EA, Lubin N, Bonner ER, Popratiloff A, Rothblat LA, Maynard TM, and LaMantia AS

Subjects

Animals, Axons ultrastructure, Behavior, Animal, Cerebral Cortex cytology, Dendrites ultrastructure, Disease Models, Animal, Entorhinal Cortex metabolism, Frontal Lobe metabolism, Gene Dosage, Mice, Mitochondria ultrastructure, Neural Pathways, Neurons ultrastructure, Synapses metabolism, Synapses ultrastructure, Cerebral Cortex metabolism, Cognitive Dysfunction genetics, DiGeorge Syndrome genetics, Mitochondria metabolism, Neurons metabolism, Reactive Oxygen Species metabolism, Thioredoxin Reductase 2 genetics

Abstract

Under-connectivity between cerebral cortical association areas may underlie cognitive deficits in neurodevelopmental disorders, including the 22q11.2 deletion syndrome (22q11DS). Using the LgDel 22q11DS mouse model, we assessed cellular, molecular, and developmental origins of under-connectivity and its consequences for cognitive function. Diminished 22q11 gene dosage reduces long-distance projections, limits axon and dendrite growth, and disrupts mitochondrial and synaptic integrity in layer 2/3 but not 5/6 projection neurons (PNs). Diminished dosage of Txnrd2, a 22q11 gene essential for reactive oxygen species catabolism in brain mitochondria, recapitulates these deficits in WT layer 2/3 PNs; Txnrd2 re-expression in LgDel layer 2/3 PNs rescues them. Anti-oxidants reverse LgDel- or Txnrd2-related layer 2/3 mitochondrial, circuit, and cognitive deficits. Accordingly, Txnrd2-mediated oxidative stress reduces layer 2/3 connectivity and impairs cognition in the context of 22q11 deletion. Anti-oxidant restoration of mitochondrial integrity, cortical connectivity, and cognitive behavior defines oxidative stress as a therapeutic target in neurodevelopmental disorders., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published

2019

11. In the line-up: deleted genes associated with DiGeorge/22q11.2 deletion syndrome: are they all suspects?

Author

Motahari Z, Moody SA, Maynard TM, and LaMantia AS

Subjects

Animals, Humans, DiGeorge Syndrome genetics, Gene Deletion, Genomics

Abstract

Background: 22q11.2 deletion syndrome (22q11DS), a copy number variation (CNV) disorder, occurs in approximately 1:4000 live births due to a heterozygous microdeletion at position 11.2 (proximal) on the q arm of human chromosome 22 (hChr22) (McDonald-McGinn and Sullivan, Medicine 90:1-18, 2011). This disorder was known as DiGeorge syndrome, Velo-cardio-facial syndrome (VCFS) or conotruncal anomaly face syndrome (CTAF) based upon diagnostic cardiovascular, pharyngeal, and craniofacial anomalies (McDonald-McGinn and Sullivan, Medicine 90:1-18, 2011; Burn et al., J Med Genet 30:822-4, 1993) before this phenotypic spectrum was associated with 22q11.2 CNVs. Subsequently, 22q11.2 deletion emerged as a major genomic lesion associated with vulnerability for several clinically defined behavioral deficits common to a number of neurodevelopmental disorders (Fernandez et al., Principles of Developmental Genetics, 2015; Robin and Shprintzen, J Pediatr 147:90-6, 2005; Schneider et al., Am J Psychiatry 171:627-39, 2014)., Results: The mechanistic relationships between heterozygously deleted 22q11.2 genes and 22q11DS phenotypes are still unknown. We assembled a comprehensive "line-up" of the 36 protein coding loci in the 1.5 Mb minimal critical deleted region on hChr22q11.2, plus 20 protein coding loci in the distal 1.5 Mb that defines the 3 Mb typical 22q11DS deletion. We categorized candidates based upon apparent primary cell biological functions. We analyzed 41 of these genes that encode known proteins to determine whether haploinsufficiency of any single 22q11.2 gene-a one gene to one phenotype correspondence due to heterozygous deletion restricted to that locus-versus complex multigenic interactions can account for single or multiple 22q11DS phenotypes., Conclusions: Our 22q11.2 functional genomic assessment does not support current theories of single gene haploinsufficiency for one or all 22q11DS phenotypes. Shared molecular functions, convergence on fundamental cell biological processes, and related consequences of individual 22q11.2 genes point to a matrix of multigenic interactions due to diminished 22q11.2 gene dosage. These interactions target fundamental cellular mechanisms essential for development, maturation, or homeostasis at subsets of 22q11DS phenotypic sites.

Published

2019

12. Oxidative stress-driven parvalbumin interneuron impairment as a common mechanism in models of schizophrenia.

Author

Steullet P, Cabungcal JH, Coyle J, Didriksen M, Gill K, Grace AA, Hensch TK, LaMantia AS, Lindemann L, Maynard TM, Meyer U, Morishita H, O'Donnell P, Puhl M, Cuenod M, and Do KQ

Subjects

Animals, Autism Spectrum Disorder genetics, Autism Spectrum Disorder metabolism, Disease Models, Animal, Gyrus Cinguli metabolism, Humans, Interneurons metabolism, Interneurons physiology, Mice, Oxidation-Reduction, Oxidative Stress physiology, Schizophrenia genetics, Schizophrenia metabolism, Oxidative Stress genetics, Parvalbumins metabolism

Abstract

Parvalbumin inhibitory interneurons (PVIs) are crucial for maintaining proper excitatory/inhibitory balance and high-frequency neuronal synchronization. Their activity supports critical developmental trajectories, sensory and cognitive processing, and social behavior. Despite heterogeneity in the etiology across schizophrenia and autism spectrum disorder, PVI circuits are altered in these psychiatric disorders. Identifying mechanism(s) underlying PVI deficits is essential to establish treatments targeting in particular cognition. On the basis of published and new data, we propose oxidative stress as a common pathological mechanism leading to PVI impairment in schizophrenia and some forms of autism. A series of animal models carrying genetic and/or environmental risks relevant to diverse etiological aspects of these disorders show PVI deficits to be all accompanied by oxidative stress in the anterior cingulate cortex. Specifically, oxidative stress is negatively correlated with the integrity of PVIs and the extracellular perineuronal net enwrapping these interneurons. Oxidative stress may result from dysregulation of systems typically affected in schizophrenia, including glutamatergic, dopaminergic, immune and antioxidant signaling. As convergent end point, redox dysregulation has successfully been targeted to protect PVIs with antioxidants/redox regulators across several animal models. This opens up new perspectives for the use of antioxidant treatments to be applied to at-risk individuals, in close temporal proximity to environmental impacts known to induce oxidative stress.

Published

2017

13. Foxd4 is essential for establishing neural cell fate and for neuronal differentiation.

Author

Sherman JH, Karpinski BA, Fralish MS, Cappuzzo JM, Dhindsa DS, Thal AG, Moody SA, LaMantia AS, and Maynard TM

Subjects

Animals, Cells, Cultured, Embryonic Stem Cells cytology, Forkhead Transcription Factors metabolism, Gene Expression Regulation, Developmental, Mice, Neural Plate cytology, Neural Plate metabolism, Neural Stem Cells cytology, Xenopus, Embryonic Stem Cells metabolism, Forkhead Transcription Factors genetics, Neural Stem Cells metabolism, Neurogenesis

Abstract

Many molecular factors required for later stages of neuronal differentiation have been identified; however, much less is known about the early events that regulate the initial establishment of the neuroectoderm. We have used an in vitro embryonic stem cell (ESC) differentiation model to investigate early events of neuronal differentiation and to define the role of mouse Foxd4, an ortholog of a forkhead-family transcription factor central to Xenopus neural plate/neuroectodermal precursor development. We found that Foxd4 is a necessary regulator of the transition from pluripotent ESC to neuroectodermal stem cell, and its expression is necessary for neuronal differentiation. Mouse Foxd4 expression is not only limited to the neural plate but it is also expressed and apparently functions to regulate neurogenesis in the olfactory placode. These in vitro results suggest that mouse Foxd4 has a similar function to its Xenopus ortholog; this was confirmed by successfully substituting murine Foxd4 for its amphibian counterpart in overexpression experiments. Thus, Foxd4 appears to regulate the initial steps in establishing neuroectodermal precursors during initial development of the nervous system., (© 2017 Wiley Periodicals, Inc.)

Published

2017

14. Balancing Act: Maintaining Amino Acid Levels in the Autistic Brain.

Author

Maynard TM and Manzini MC

Subjects

Amino Acids, Autistic Disorder, Brain

Abstract

The ever-expanding number of genes that are mutated in autism is showing us how imbalances in fundamental cellular processes can lead to disease. A recent study by Tărlungeanu et al. (2016) identifies a form of ASD resulting from a failure of the brain to properly import amino acids., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

15. A cellular and molecular mosaic establishes growth and differentiation states for cranial sensory neurons.

Author

Karpinski BA, Bryan CA, Paronett EM, Baker JL, Fernandez A, Horvath A, Maynard TM, Moody SA, and LaMantia AS

Subjects

Animals, Apoptosis, Axons physiology, Cell Differentiation, Cell Lineage, Cranial Nerves embryology, Ectoderm cytology, Fibroblast Growth Factors physiology, Ganglia, Sensory cytology, Gene Expression Regulation, Developmental physiology, Luminescent Proteins analysis, Luminescent Proteins genetics, Mice, Mice, Inbred C57BL, Neural Crest cytology, Neurogenesis, Transcription Factors genetics, Tretinoin physiology, Wnt1 Protein physiology, Cranial Nerves cytology, Sensory Receptor Cells cytology

Abstract

We compared apparent origins, cellular diversity and regulation of initial axon growth for differentiating cranial sensory neurons. We assessed the molecular and cellular composition of the developing olfactory and otic placodes, and cranial sensory ganglia to evaluate contributions of ectodermal placode versus neural crest at each site. Special sensory neuron populations-the olfactory and otic placodes, as well as those in vestibulo-acoustic ganglion- are entirely populated with cells expressing cranial placode-associated, rather than neural crest-associated markers. The remaining cranial sensory ganglia are a mosaic of cells that express placode-associated as well as neural crest-associated markers. We found two distinct populations of neural crest in the cranial ganglia: the first, as expected, is labeled by Wnt1:Cre mediated recombination. The second is not labeled by Wnt1:Cre recombination, and expresses both Sox10 and FoxD3. These populations-Wnt1:Cre recombined, and Sox10/Foxd3-expressing- are proliferatively distinct from one another. Together, the two neural crest-associated populations are substantially more proliferative than their placode-associated counterparts. Nevertheless, the apparently placode- and neural crest-associated populations are similarly sensitive to altered signaling that compromises cranial morphogenesis and differentiation. Acute disruption of either Fibroblast growth factor (Fgf) or Retinoic acid (RA) signaling alters axon growth and cell death, but does not preferentially target any of the three distinct populations. Apparently, mosaic derivation and diversity of precursors and early differentiating neurons, modulated uniformly by local signals, supports early cranial sensory neuron differentiation and growth., (Copyright © 2016 Elsevier Inc. All rights reserved.)

Published

2016

16. Functional Divergence of the Nuclear Receptor NR2C1 as a Modulator of Pluripotentiality During Hominid Evolution.

Author

Baker JL, Dunn KA, Mingrone J, Wood BA, Karpinski BA, Sherwood CC, Wildman DE, Maynard TM, and Bielawski JP

Subjects

Animals, Cell Line, Conserved Sequence, Humans, Mice, Nanog Homeobox Protein genetics, Nanog Homeobox Protein metabolism, Nuclear Receptor Subfamily 2, Group C, Member 1 chemistry, Octamer Transcription Factor-3 genetics, Octamer Transcription Factor-3 metabolism, Phosphoenolpyruvate Carboxykinase (ATP) genetics, Phosphoenolpyruvate Carboxykinase (ATP) metabolism, Pluripotent Stem Cells metabolism, Protein Domains, Cell Differentiation genetics, Evolution, Molecular, Hominidae genetics, Nuclear Receptor Subfamily 2, Group C, Member 1 genetics, Pluripotent Stem Cells cytology

Abstract

Genes encoding nuclear receptors (NRs) are attractive as candidates for investigating the evolution of gene regulation because they (1) have a direct effect on gene expression and (2) modulate many cellular processes that underlie development. We employed a three-phase investigation linking NR molecular evolution among primates with direct experimental assessment of NR function. Phase 1 was an analysis of NR domain evolution and the results were used to guide the design of phase 2, a codon-model-based survey for alterations of natural selection within the hominids. By using a series of reliability and robustness analyses we selected a single gene, NR2C1, as the best candidate for experimental assessment. We carried out assays to determine whether changes between the ancestral and extant NR2C1s could have impacted stem cell pluripotency (phase 3). We evaluated human, chimpanzee, and ancestral NR2C1 for transcriptional modulation of Oct4 and Nanog (key regulators of pluripotency and cell lineage commitment), promoter activity for Pepck (a proxy for differentiation in numerous cell types), and average size of embryological stem cell colonies (a proxy for the self-renewal capacity of pluripotent cells). Results supported the signal for alteration of natural selection identified in phase 2. We suggest that adaptive evolution of gene regulation has impacted several aspects of pluripotentiality within primates. Our study illustrates that the combination of targeted evolutionary surveys and experimental analysis is an effective strategy for investigating the evolution of gene regulation with respect to developmental phenotypes., (Copyright © 2016 by the Genetics Society of America.)

Published

2016

17. Neural transcription factors bias cleavage stage blastomeres to give rise to neural ectoderm.

Author

Gaur S, Mandelbaum M, Herold M, Majumdar HD, Neilson KM, Maynard TM, Mood K, Daar IO, and Moody SA

Subjects

Animals, Blastomeres metabolism, Blastula growth & development, Ectoderm metabolism, Forkhead Transcription Factors biosynthesis, Gastrula growth & development, Gene Expression Regulation, Developmental, Humans, Mice, Neural Plate metabolism, Transcription Factors biosynthesis, Transcription Factors genetics, Xenopus Proteins biosynthesis, Xenopus Proteins genetics, Xenopus laevis genetics, Xenopus laevis growth & development, Zygote growth & development, Cell Differentiation genetics, Ectoderm growth & development, Forkhead Transcription Factors genetics, Neural Plate growth & development

Abstract

The decision by embryonic ectoderm to give rise to epidermal versus neural derivatives is the result of signaling events during blastula and gastrula stages. However, there also is evidence in Xenopus that cleavage stage blastomeres contain maternally derived molecules that bias them toward a neural fate. We used a blastomere explant culture assay to test whether maternally deposited transcription factors bias 16-cell blastomere precursors of epidermal or neural ectoderm to express early zygotic neural genes in the absence of gastrulation interactions or exogenously supplied signaling factors. We found that Foxd4l1, Zic2, Gmnn, and Sox11 each induced explants made from ventral, epidermis-producing blastomeres to express early neural genes, and that at least some of the Foxd4l1 and Zic2 activities are required at cleavage stages. Similarly, providing extra Foxd4l1 or Zic2 to explants made from dorsal, neural plate-producing blastomeres significantly increased the expression of early neural genes, whereas knocking down either significantly reduced them. These results show that maternally delivered transcription factors bias cleavage stage blastomeres to a neural fate. We demonstrate that mouse and human homologs of Foxd4l1 have similar functional domains compared to the frog protein, as well as conserved transcriptional activities when expressed in Xenopus embryos and blastomere explants. genesis 54:334-349, 2016. © 2016 Wiley Periodicals, Inc., (© 2016 Wiley Periodicals, Inc.)

Published

2016

18. MicroRNAs Are Involved in the Development of Morphine-Induced Analgesic Tolerance and Regulate Functionally Relevant Changes in Serpini1.

Author

Tapocik JD, Ceniccola K, Mayo CL, Schwandt ML, Solomon M, Wang BD, Luu TV, Olender J, Harrigan T, Maynard TM, Elmer GI, and Lee NH

Abstract

Long-term opioid treatment results in reduced therapeutic efficacy and in turn leads to an increase in the dose required to produce equivalent pain relief and alleviate break-through or insurmountable pain. Altered gene expression is a likely means for inducing long-term neuroadaptations responsible for tolerance. Studies conducted by our laboratory (Tapocik et al., 2009) revealed a network of gene expression changes occurring in canonical pathways involved in neuroplasticity, and uncovered miRNA processing as a potential mechanism. In particular, the mRNA coding the protein responsible for processing miRNAs, Dicer1, was positively correlated with the development of analgesic tolerance. The purpose of the present study was to test the hypothesis that miRNAs play a significant role in the development of analgesic tolerance as measured by thermal nociception. Dicer1 knockdown, miRNA profiling, bioinformatics, and confirmation of high value targets were used to test the proposition. Regionally targeted Dicer1 knockdown (via shRNA) had the anticipated consequence of eliminating the development of tolerance in C57BL/6J (B6) mice, thus supporting the involvement of miRNAs in the development of tolerance. MiRNA expression profiling identified a core set of chronic morphine-regulated miRNAs (miR's 27a, 9, 483, 505, 146b, 202). Bioinformatics approaches were implemented to identify and prioritize their predicted target mRNAs. We focused our attention on miR27a and its predicted target serpin peptidase inhibitor clade I (Serpini1) mRNA, a transcript known to be intricately involved in dendritic spine density regulation in a manner consistent with chronic morphine's consequences and previously found to be correlated with the development of analgesic tolerance. In vitro reporter assay confirmed the targeting of the Serpini1 3'-untranslated region by miR27a. Interestingly miR27a was found to positively regulate Serpini1 mRNA and protein levels in multiple neuronal cell lines. Lastly, Serpini1 knockout mice developed analgesic tolerance at a slower rate than wild-type mice thus confirming a role for the protein in analgesic tolerance. Overall, these results provide evidence to support a specific role for miR27a and Serpini1 in the behavioral response to chronic opioid administration (COA) and suggest that miRNA expression and mRNA targeting may underlie the neuroadaptations that mediate tolerance to the analgesic effects of morphine.

Published

2016

19. Hard to swallow: Developmental biological insights into pediatric dysphagia.

Author

LaMantia AS, Moody SA, Maynard TM, Karpinski BA, Zohn IE, Mendelowitz D, Lee NH, and Popratiloff A

Subjects

Animals, Child, Disease Models, Animal, Humans, Models, Biological, Nerve Net physiopathology, Deglutition Disorders pathology, Growth and Development

Abstract

Pediatric dysphagia-feeding and swallowing difficulties that begin at birth, last throughout childhood, and continue into maturity--is one of the most common, least understood complications in children with developmental disorders. We argue that a major cause of pediatric dysphagia is altered hindbrain patterning during pre-natal development. Such changes can compromise craniofacial structures including oropharyngeal muscles and skeletal elements as well as motor and sensory circuits necessary for normal feeding and swallowing. Animal models of developmental disorders that include pediatric dysphagia in their phenotypic spectrum can provide mechanistic insight into pathogenesis of feeding and swallowing difficulties. A fairly common human genetic developmental disorder, DiGeorge/22q11.2 Deletion Syndrome (22q11DS) includes a substantial incidence of pediatric dysphagia in its phenotypic spectrum. Infant mice carrying a parallel deletion to 22q11DS patients have feeding and swallowing difficulties that approximate those seen in pediatric dysphagia. Altered hindbrain patterning, craniofacial malformations, and changes in cranial nerve growth prefigure these difficulties. Thus, in addition to craniofacial and pharyngeal anomalies that arise independently of altered neural development, pediatric dysphagia may result from disrupted hindbrain patterning and its impact on peripheral and central neural circuit development critical for feeding and swallowing. The mechanisms that disrupt hindbrain patterning and circuitry may provide a foundation to develop novel therapeutic approaches for improved clinical management of pediatric dysphagia., (Copyright © 2015. Published by Elsevier Inc.)

Published

2016

20. Testicular receptor 2, Nr2c1, is associated with stem cells in the developing olfactory epithelium and other cranial sensory and skeletal structures.

Author

Baker JL, Wood B, Karpinski BA, LaMantia AS, and Maynard TM

Subjects

Animals, Brain embryology, Brain metabolism, Facial Bones embryology, Facial Bones metabolism, Ganglia, Sensory embryology, Ganglia, Sensory metabolism, Gene Expression Profiling, Mice, Neural Stem Cells metabolism, Olfactory Bulb metabolism, Olfactory Mucosa cytology, Olfactory Mucosa metabolism, Skull cytology, Skull metabolism, Telencephalon metabolism, Tooth embryology, Tooth metabolism, Nuclear Receptor Subfamily 2, Group C, Member 1 biosynthesis, Olfactory Mucosa embryology, Skull embryology, Stem Cells metabolism

Abstract

Comparative genomic analysis of the nuclear receptor family suggests that the testicular receptor 2, Nr2c1, undergoes positive selection in the human-chimpanzee clade based upon a significant increase in nonsynonymous compared to synonymous substitutions. Previous in situ analyses of Nr2c1 lacked the temporal range and spatial resolution necessary to characterize cellular expression of this gene from early to mid gestation, when many nuclear receptors are key regulators of tissue specific stem or progenitor cells. Thus, we asked whether Nr2c1 protein is associated with stem cell populations in the mid-gestation mouse embryo. Nr2c1 is robustly expressed in the developing olfactory epithelium. Its expression in the olfactory epithelium shifts from multiple progenitor classes at early stages to primarily transit amplifying cells later in olfactory epithelium development. In the early developing central nervous system, Nr2c1 is limited to the anterior telencephalon/olfactory bulb anlagen, coincident with Nestin-positive neuroepithelial stem cells. Nr2c1 is also seen in additional cranial sensory specializations including cells surrounding the mystacial vibrissae, the retinal pigment epithelium and Scarpa's ganglion. Nr2c1 was also detected in a subset of mesenchymal cells in developing teeth and cranial bones. The timing and distribution of embryonic expression suggests that Nr2c1 is primarily associated with the early genesis of mammalian cranial sensory neurons and craniofacial skeletal structures. Thus, Nr2c1 may be a candidate for mediating parallel adaptive changes in cranial neural sensory specializations such as the olfactory epithelium, retina and mystacial vibrissae and in non-neural craniofacial features including teeth., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2016

21. Ranbp1, Deleted in DiGeorge/22q11.2 Deletion Syndrome, is a Microcephaly Gene That Selectively Disrupts Layer 2/3 Cortical Projection Neuron Generation.

Author

Paronett EM, Meechan DW, Karpinski BA, LaMantia AS, and Maynard TM

Subjects

Animals, Cell Polarity, Cell Proliferation genetics, Cerebral Cortex physiopathology, DiGeorge Syndrome physiopathology, Lateral Ventricles embryology, Lateral Ventricles physiopathology, Mice, Mice, Inbred C57BL, Mice, Knockout, Neuroepithelial Cells physiology, Nuclear Proteins genetics, Cerebral Cortex embryology, DiGeorge Syndrome embryology, DiGeorge Syndrome genetics, Microcephaly genetics, Neural Stem Cells physiology, Neurogenesis genetics, Nuclear Proteins physiology

Abstract

Ranbp1, a Ran GTPase-binding protein implicated in nuclear/cytoplasmic trafficking, is included within the DiGeorge/22q11.2 Deletion Syndrome (22q11.2 DS) critical region associated with behavioral impairments including autism and schizophrenia. Ranbp1 is highly expressed in the developing forebrain ventricular/subventricular zone but has no known obligate function during brain development. We assessed the role of Ranbp1 in a targeted mouse mutant. Ranbp1(-/-) mice are not recovered live at birth, and over 60% of Ranbp1(-/-) embryos are exencephalic. Non-exencephalic Ranbp1(-/-) embryos are microcephalic, and proliferation of cortical progenitors is altered. At E10.5, radial progenitors divide more slowly in the Ranpb1(-/-) dorsal pallium. At E14.5, basal, but not apical/radial glial progenitors, are compromised in the cortex. In both E10.5 apical and E14.5 basal progenitors, M phase of the cell cycle appears selectively retarded by loss of Ranpb1 function. Ranbp1(-/-)-dependent proliferative deficits substantially diminish the frequency of layer 2/3, but not layer 5/6 cortical projection neurons. Ranbp1(-/-) cortical phenotypes parallel less severe alterations in LgDel mice that carry a deletion parallel to many (but not all) 22q11.2 DS patients. Thus, Ranbp1 emerges as a microcephaly gene within the 22q11.2 deleted region that may contribute to altered cortical precursor proliferation and neurogenesis associated with broader 22q11.2 deletion., (© The Author 2014. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published

2015

22. Modeling a model: Mouse genetics, 22q11.2 Deletion Syndrome, and disorders of cortical circuit development.

Author

Meechan DW, Maynard TM, Tucker ES, Fernandez A, Karpinski BA, Rothblat LA, and LaMantia AS

Subjects

Animals, Cerebral Cortex pathology, Disease Models, Animal, Humans, Schizophrenia genetics, Chromosomes, Human, Pair 22 genetics, DiGeorge Syndrome genetics, Genetic Predisposition to Disease genetics, Mice

Abstract

Understanding the developmental etiology of autistic spectrum disorders, attention deficit/hyperactivity disorder and schizophrenia remains a major challenge for establishing new diagnostic and therapeutic approaches to these common, difficult-to-treat diseases that compromise neural circuits in the cerebral cortex. One aspect of this challenge is the breadth and overlap of ASD, ADHD, and SCZ deficits; another is the complexity of mutations associated with each, and a third is the difficulty of analyzing disrupted development in at-risk or affected human fetuses. The identification of distinct genetic syndromes that include behavioral deficits similar to those in ASD, ADHC and SCZ provides a critical starting point for meeting this challenge. We summarize clinical and behavioral impairments in children and adults with one such genetic syndrome, the 22q11.2 Deletion Syndrome, routinely called 22q11DS, caused by micro-deletions of between 1.5 and 3.0 MB on human chromosome 22. Among many syndromic features, including cardiovascular and craniofacial anomalies, 22q11DS patients have a high incidence of brain structural, functional, and behavioral deficits that reflect cerebral cortical dysfunction and fall within the spectrum that defines ASD, ADHD, and SCZ. We show that developmental pathogenesis underlying this apparent genetic "model" syndrome in patients can be defined and analyzed mechanistically using genomically accurate mouse models of the deletion that causes 22q11DS. We conclude that "modeling a model", in this case 22q11DS as a model for idiopathic ASD, ADHD and SCZ, as well as other behavioral disorders like anxiety frequently seen in 22q11DS patients, in genetically engineered mice provides a foundation for understanding the causes and improving diagnosis and therapy for these disorders of cortical circuit development., (Copyright © 2015 Elsevier Ltd. All rights reserved.)

Published

2015

23. Cognitive ability is associated with altered medial frontal cortical circuits in the LgDel mouse model of 22q11.2DS.

Author

Meechan DW, Rutz HL, Fralish MS, Maynard TM, Rothblat LA, and LaMantia AS

Subjects

Animals, Discrimination Learning, Disease Models, Animal, Executive Function, Frontal Lobe cytology, Interneurons pathology, Male, Mice, Mice, Inbred C57BL, Neurons pathology, Synapses pathology, 22q11 Deletion Syndrome pathology, 22q11 Deletion Syndrome psychology, Behavior, Animal, Cognition, Frontal Lobe pathology, Nerve Net pathology

Abstract

We established a relationship between cognitive deficits and cortical circuits in the LgDel model of 22q11 Deletion Syndrome (22q11DS)-a genetic syndrome with one of the most significant risks for schizophrenia and autism. In the LgDel mouse, optimal acquisition, execution, and reversal of a visually guided discrimination task, comparable to executive function tasks in primates including humans, are compromised; however, there is significant individual variation in degree of impairment. The task relies critically on the integrity of circuits in medial anterior frontal cortical regions. Accordingly, we analyzed neuronal changes that reflect previously defined 22q11DS-related alterations of cortical development in the medial anterior frontal cortex of the behaviorally characterized LgDel mice. Interneuron placement, synapse distribution, and projection neuron frequency are altered in this region. The magnitude of one of these changes, layer 2/3 projection neuron frequency, is a robust predictor of behavioral performance: it is substantially and selectively lower in animals with the most significant behavioral deficits. These results parallel correlations of volume reduction and altered connectivity in comparable cortical regions with diminished executive function in 22q11DS patients. Apparently, 22q11 deletion alters behaviorally relevant circuits in a distinct cortical region that are essential for cognitive function., (© The Author 2013. Published by Oxford University Press. All rights reserved. For Permissions, please e-mail: journals.permissions@oup.com.)

Published

2015

24. Dysphagia and disrupted cranial nerve development in a mouse model of DiGeorge (22q11) deletion syndrome.

Author

Karpinski BA, Maynard TM, Fralish MS, Nuwayhid S, Zohn IE, Moody SA, and LaMantia AS

Subjects

Animals, Animals, Newborn, Body Patterning genetics, Craniofacial Abnormalities pathology, Craniofacial Abnormalities physiopathology, Deglutition, Deglutition Disorders genetics, Deglutition Disorders physiopathology, DiGeorge Syndrome, Disease Models, Animal, Embryo, Mammalian abnormalities, Embryo, Mammalian pathology, Feeding Behavior, Female, Gene Dosage, Gene Expression Regulation, Developmental, Male, Mice, Phenotype, Rhombencephalon abnormalities, Rhombencephalon embryology, Rhombencephalon pathology, Signal Transduction, T-Box Domain Proteins metabolism, Tretinoin metabolism, Chromosome Deletion, Cranial Nerves embryology, Cranial Nerves pathology, Deglutition Disorders embryology, Deglutition Disorders pathology

Abstract

We assessed feeding-related developmental anomalies in the LgDel mouse model of chromosome 22q11 deletion syndrome (22q11DS), a common developmental disorder that frequently includes perinatal dysphagia--debilitating feeding, swallowing and nutrition difficulties from birth onward--within its phenotypic spectrum. LgDel pups gain significantly less weight during the first postnatal weeks, and have several signs of respiratory infections due to food aspiration. Most 22q11 genes are expressed in anlagen of craniofacial and brainstem regions critical for feeding and swallowing, and diminished expression in LgDel embryos apparently compromises development of these regions. Palate and jaw anomalies indicate divergent oro-facial morphogenesis. Altered expression and patterning of hindbrain transcriptional regulators, especially those related to retinoic acid (RA) signaling, prefigures these disruptions. Subsequently, gene expression, axon growth and sensory ganglion formation in the trigeminal (V), glossopharyngeal (IX) or vagus (X) cranial nerves (CNs) that innervate targets essential for feeding, swallowing and digestion are disrupted. Posterior CN IX and X ganglia anomalies primarily reflect diminished dosage of the 22q11DS candidate gene Tbx1. Genetic modification of RA signaling in LgDel embryos rescues the anterior CN V phenotype and returns expression levels or pattern of RA-sensitive genes to those in wild-type embryos. Thus, diminished 22q11 gene dosage, including but not limited to Tbx1, disrupts oro-facial and CN development by modifying RA-modulated anterior-posterior hindbrain differentiation. These disruptions likely contribute to dysphagia in infants and young children with 22q11DS.

Published

2014

25. On becoming neural: what the embryo can tell us about differentiating neural stem cells.

Author

Moody SA, Klein SL, Karpinski BA, Maynard TM, and Lamantia AS

Abstract

THE EARLIEST STEPS OF EMBRYONIC NEURAL DEVELOPMENT ARE ORCHESTRATED BY SETS OF TRANSCRIPTION FACTORS THAT CONTROL AT LEAST THREE PROCESSES: the maintenance of proliferative, pluripotent precursors that expand the neural ectoderm; their transition to neurally committed stem cells comprising the neural plate; and the onset of differentiation of neural progenitors. The transition from one step to the next requires the sequential activation of each gene set and then its down-regulation at the correct developmental times. Herein, we review how these gene sets interact in a transcriptional network to regulate these early steps in neural development. A key gene in this regulatory network is FoxD4L1, a member of the forkhead box (Fox) family of transcription factors. Knock-down experiments in Xenopus embryos show that FoxD4L1 is required for the expression of the other neural transcription factors, whereas increased FoxD4L1 levels have three different effects on these genes: up-regulation of neural ectoderm precursor genes; transient down-regulation of neural plate stem cell genes; and down-regulation of neural progenitor differentiation genes. These different effects indicate that FoxD4L1 maintains neural ectodermal precursors in an immature, proliferative state, and counteracts premature neural stem cell and neural progenitor differentiation. Because it both up-regulates and down-regulates genes, we characterized the regions of the FoxD4L1 protein that are specifically involved in these transcriptional functions. We identified a transcriptional activation domain in the N-terminus and at least two domains in the C-terminus that are required for transcriptional repression. These functional domains are highly conserved in the mouse and human homologues. Preliminary studies of the related FoxD4 gene in cultured mouse embryonic stem cells indicate that it has a similar role in promoting immature neural ectodermal precursors and delaying neural progenitor differentiation. These studies in Xenopus embryos and mouse embryonic stem cells indicate that FoxD4L1/FoxD4 has the important function of regulating the balance between the genes that expand neural ectodermal precursors and those that promote neural stem/progenitor differentiation. Thus, regulating the level of expression of FoxD4 may be important in stem cell protocols designed to create immature neural cells for therapeutic uses.

Published

2013

26. 22q11 Gene dosage establishes an adaptive range for sonic hedgehog and retinoic acid signaling during early development.

Author

Maynard TM, Gopalakrishna D, Meechan DW, Paronett EM, Newbern JM, and LaMantia AS

Subjects

Animals, Bone Morphogenetic Proteins metabolism, Female, Fibroblast Growth Factors metabolism, Gene Expression Regulation, Developmental, Humans, Mice, Mice, Knockout, Morphogenesis genetics, Neural Tube embryology, Neural Tube metabolism, Phenotype, Adaptation, Biological, DiGeorge Syndrome genetics, DiGeorge Syndrome metabolism, Gene Dosage, Hedgehog Proteins metabolism, Signal Transduction, Tretinoin metabolism

Abstract

We asked whether key morphogenetic signaling pathways interact with 22q11 gene dosage to modulate the severity of cranial or cardiac anomalies in DiGeorge/22q1 deletion syndrome (22q11DS). Sonic hedgehog (Shh) and retinoic acid (RA) signaling is altered in the brain and heart-clinically significant 22q11DS phenotypic sites-in LgDel mouse embryos, an established 22q11DS model. LgDel embryos treated with cyclopamine, an Shh inhibitor, or carrying mutations in Gli3(Xtj), an Shh-signaling effector, have morphogenetic anomalies that are either not seen, or seen at significantly lower frequencies in control or single-mutant embryos. Similarly, RA exposure or genetic loss of RA function via heterozygous mutation of the RA synthetic enzyme Raldh2 induces novel cranial anomalies and enhances cardiovascular phenotypes in LgDel but not other genotypes. These changes are not seen in heterozygous Tbx1 mutant embryos-a 22q11 gene thought to explain much of 22q11DS pathogenesis-in which Shh or RA signaling has been similarly modified. Our results suggest that full dosage of 22q11 genes beyond Tbx1 establish an adaptive range for morphogenetic signaling via Shh and RA. When this adaptive range is constricted by diminished dosage of 22q11 genes, embryos are sensitized to otherwise benign changes in Shh and RA signaling. Such sensitization, in the face of environmental or genetic factors that modify Shh or RA signaling, may explain variability in 22q11DS morphogenetic phenotypes.

Published

2013

27. Cxcr4 regulation of interneuron migration is disrupted in 22q11.2 deletion syndrome.

Author

Meechan DW, Tucker ES, Maynard TM, and LaMantia AS

Subjects

Animals, Cerebral Cortex embryology, Cerebral Cortex pathology, Heterozygote, Mice, Mice, Inbred C57BL, Mutation genetics, Parvalbumins metabolism, Cell Movement genetics, DiGeorge Syndrome metabolism, DiGeorge Syndrome pathology, Interneurons metabolism, Interneurons pathology, Receptors, CXCR4 metabolism

Abstract

Interneurons are thought to be a primary pathogenic target for several behavioral disorders that arise during development, including schizophrenia and autism. It is not known, however, whether genetic lesions associated with these diseases disrupt established molecular mechanisms of interneuron development. We found that diminished 22q11.2 gene dosage-the primary genetic lesion in 22q11.2 deletion syndrome (22q11.2 DS)-specifically compromises the distribution of early-generated parvalbumin-expressing interneurons in the Large Deletion (LgDel) 22q11.2DS mouse model. This change reflects cell-autonomous disruption of interneuron migration caused by altered expression of the cytokine C-X-C chemokine receptor type 4 (Cxcr4), an established regulator of this process. Cxcr4 is specifically reduced in LgDel migrating interneurons, and genetic analysis confirms that diminished Cxcr4 alters interneuron migration in LgDel mice. Thus, diminished 22q11.2 gene dosage disrupts cortical circuit development by modifying a critical molecular signaling pathway via Cxcr4 that regulates cortical interneuron migration and placement.

Published

2012

28. Exome sequencing and functional validation in zebrafish identify GTDC2 mutations as a cause of Walker-Warburg syndrome.

Author

Manzini MC, Tambunan DE, Hill RS, Yu TW, Maynard TM, Heinzen EL, Shianna KV, Stevens CR, Partlow JN, Barry BJ, Rodriguez J, Gupta VA, Al-Qudah AK, Eyaid WM, Friedman JM, Salih MA, Clark R, Moroni I, Mora M, Beggs AH, Gabriel SB, and Walsh CA

Subjects

Exome, Humans, Mutation, Glycosyltransferases genetics, Walker-Warburg Syndrome genetics

Abstract

Whole-exome sequencing (WES), which analyzes the coding sequence of most annotated genes in the human genome, is an ideal approach to studying fully penetrant autosomal-recessive diseases, and it has been very powerful in identifying disease-causing mutations even when enrollment of affected individuals is limited by reduced survival. In this study, we combined WES with homozygosity analysis of consanguineous pedigrees, which are informative even when a single affected individual is available, to identify genetic mutations responsible for Walker-Warburg syndrome (WWS), a genetically heterogeneous autosomal-recessive disorder that severely affects the development of the brain, eyes, and muscle. Mutations in seven genes are known to cause WWS and explain 50%-60% of cases, but multiple additional genes are expected to be mutated because unexplained cases show suggestive linkage to diverse loci. Using WES in consanguineous WWS-affected families, we found multiple deleterious mutations in GTDC2 (also known as AGO61). GTDC2's predicted role as an uncharacterized glycosyltransferase is consistent with the function of other genes that are known to be mutated in WWS and that are involved in the glycosylation of the transmembrane receptor dystroglycan. Therefore, to explore the role of GTDC2 loss of function during development, we used morpholino-mediated knockdown of its zebrafish ortholog, gtdc2. We found that gtdc2 knockdown in zebrafish replicates all WWS features (hydrocephalus, ocular defects, and muscular dystrophy), strongly suggesting that GTDC2 mutations cause WWS., (Copyright © 2012 The American Society of Human Genetics. Published by Elsevier Inc. All rights reserved.)

Published

2012

29. Three phases of DiGeorge/22q11 deletion syndrome pathogenesis during brain development: patterning, proliferation, and mitochondrial functions of 22q11 genes.

Author

Meechan DW, Maynard TM, Tucker ES, and LaMantia AS

Subjects

Animals, Brain physiology, Cell Movement, Cell Proliferation, Gene Dosage, Humans, Mitochondria genetics, Morphogenesis, Phenotype, 22q11 Deletion Syndrome genetics, 22q11 Deletion Syndrome pathology, 22q11 Deletion Syndrome physiopathology, Brain abnormalities, Brain embryology, Chromosomes, Human, Pair 22 genetics, DiGeorge Syndrome genetics, DiGeorge Syndrome pathology, DiGeorge Syndrome physiopathology, Mitochondria metabolism, Neurogenesis

Abstract

DiGeorge, or 22q11 deletion syndrome (22q11DS), the most common survivable human genetic deletion disorder, is caused by deletion of a minimum of 32 contiguous genes on human chromosome 22, and presumably results from diminished dosage of one, some, or all of these genes--particularly during development. Nevertheless, the normal functions of 22q11 genes in the embryo or neonate, and their contribution to developmental pathogenesis that must underlie 22q11DS are not well understood. Our data suggests that a substantial number of 22q11 genes act specifically and in concert to mediate early morphogenetic interactions and subsequent cellular differentiation at phenotypically compromised sites--the limbs, heart, face and forebrain. When dosage of a broad set of these genes is diminished, early morphogenesis is altered, and initial 22q11DS phenotypes are established. Thereafter, functionally similar subsets of 22q11 genes--especially those that influence the cell cycle or mitochondrial function--remain expressed, particularly in the developing cerebral cortex, to regulate neurogenesis and synaptic development. When dosage of these genes is diminished, numbers, placement and connectivity of neurons and circuits essential for normal behavior may be disrupted. Such disruptions likely contribute to vulnerability for schizophrenia, autism, or attention deficit/hyperactivity disorder seen in most 22q11DS patients., (Copyright © 2010 ISDN. Published by Elsevier Ltd. All rights reserved.)

Published

2011

30. Comt1 genotype and expression predicts anxiety and nociceptive sensitivity in inbred strains of mice.

Author

Segall SK, Nackley AG, Diatchenko L, Lariviere WR, Lu X, Marron JS, Grabowski-Boase L, Walker JR, Slade G, Gauthier J, Bailey JS, Steffy BM, Maynard TM, Tarantino LM, and Wiltshire T

Subjects

Animals, Anxiety enzymology, Catechol O-Methyltransferase metabolism, Exploratory Behavior physiology, Female, Male, Maze Learning physiology, Mice, Mice, Inbred Strains, Mutagenesis, Insertional, Pain enzymology, RNA, Messenger analysis, Species Specificity, Anxiety genetics, Catechol O-Methyltransferase genetics, Hippocampus enzymology, Pain genetics, Pain Threshold physiology

Abstract

Catechol-O-methyltransferase (COMT) is a ubiquitously expressed enzyme that maintains basic biologic functions by inactivating catechol substrates. In humans, polymorphic variance at the COMT locus has been associated with modulation of pain sensitivity and risk for developing psychiatric disorders. A functional haplotype associated with increased pain sensitivity was shown to result in decreased COMT activity by altering mRNA secondary structure-dependent protein translation. However, the exact mechanisms whereby COMT modulates pain sensitivity and behavior remain unclear and can be further studied in animal models. We have assessed Comt1 gene expression levels in multiple brain regions in inbred strains of mice and have discovered that Comt1 is differentially expressed among the strains, and this differential expression is cis-regulated. A B2 short interspersed nuclear element (SINE) was inserted in the 3'-untranslated region (3'-UTR) of Comt1 in 14 strains generating a common haplotype that correlates with gene expression. Experiments using mammalian expression vectors of full-length cDNA clones with and without the SINE element show that strains with the SINE haplotype (+SINE) have greater Comt1 enzymatic activity. +SINE mice also exhibit behavioral differences in anxiety assays and decreased pain sensitivity. These results suggest that a haplotype, defined by a 3'-UTR B2 SINE element, regulates Comt1 expression and some mouse behaviors., (© 2010 The Authors. Genes, Brain and Behavior © 2010 Blackwell Publishing Ltd and International Behavioural and Neural Genetics Society.)

Published

2010

31. Specific mesenchymal/epithelial induction of olfactory receptor, vomeronasal, and gonadotropin-releasing hormone (GnRH) neurons.

Author

Rawson NE, Lischka FW, Yee KK, Peters AZ, Tucker ES, Meechan DW, Zirlinger M, Maynard TM, Burd GB, Dulac C, Pevny L, and LaMantia AS

Subjects

Animals, Embryo, Mammalian, Epithelium metabolism, Mice, Mice, Transgenic, Morphogenesis, Olfactory Mucosa cytology, Olfactory Mucosa metabolism, Signal Transduction, Transcription Factors metabolism, Cell Differentiation physiology, Gonadotropin-Releasing Hormone metabolism, Neurons cytology, Neurons metabolism, Olfactory Receptor Neurons metabolism

Abstract

We asked whether specific mesenchymal/epithelial (M/E) induction generates olfactory receptor neurons (ORNs), vomeronasal neurons (VRNs), and gonadotropin-releasing hormone (GnRH) neurons, the major neuron classes associated with the olfactory epithelium (OE). To assess specificity of M/E-mediated neurogenesis, we compared the influence of frontonasal mesenchyme on frontonasal epithelium, which becomes the OE, with that of the forelimb bud. Despite differences in position, morphogenetic and cytogenic capacity, both mesenchymal tissues support neurogenesis, expression of several signaling molecules and neurogenic transcription factors in the frontonasal epithelium. Only frontonasal mesenchyme, however, supports OE-specific patterning and activity of a subset of signals and factors associated with OE differentiation. Moreover, only appropriate pairing of frontonasal epithelial and mesenchymal partners yields ORNs, VRNs, and GnRH neurons. Accordingly, the position and molecular identity of specialized frontonasal epithelia and mesenchyme early in gestation and subsequent inductive interactions specify the genesis and differentiation of peripheral chemosensory and neuroendocrine neurons.

Published

2010

32. Developmental and degenerative features in a complicated spastic paraplegia.

Author

Manzini MC, Rajab A, Maynard TM, Mochida GH, Tan WH, Nasir R, Hill RS, Gleason D, Al Saffar M, Partlow JN, Barry BJ, Vernon M, LaMantia AS, and Walsh CA

Subjects

Adolescent, Adult, Cell Cycle Proteins, Child, Preschool, Chromosome Mapping, DNA Mutational Analysis methods, Family Health, Female, Humans, Magnetic Resonance Imaging, Male, Oman, Paraplegia pathology, Proteins metabolism, RNA, Messenger genetics, Young Adult, Genetic Predisposition to Disease genetics, Neurodegenerative Diseases etiology, Paraplegia complications, Paraplegia genetics, Polymorphism, Single Nucleotide genetics, Proteins genetics

Abstract

Objective: We sought to explore the genetic and molecular causes of Troyer syndrome, one of several complicated hereditary spastic paraplegias (HSPs). Troyer syndrome had been thought to be restricted to the Amish; however, we identified 2 Omani families with HSP, short stature, dysarthria and developmental delay-core features of Troyer syndrome-and a novel mutation in the SPG20 gene, which is also mutated in the Amish. In addition, we analyzed SPG20 expression throughout development to infer how disruption of this gene might generate the constellation of developmental and degenerative Troyer syndrome phenotypes., Methods: Clinical characterization of 2 non-Amish families with Troyer syndrome was followed by linkage and sequencing analysis. Quantitative polymerase chain reaction and in situ hybridization analysis of SPG20 expression were carried out in embryonic and adult human and mouse tissue., Results: Two Omani families carrying a novel SPG20 mutation displayed clinical features remarkably similar to the Amish patients with Troyer syndrome. SPG20 mRNA is expressed broadly but at low relative levels in the adult brain; however, it is robustly and specifically expressed in the limbs, face, and brain during early morphogenesis., Interpretation: Null mutations in SPG20 cause Troyer syndrome, a specific clinical entity with developmental and degenerative features. Maximal expression of SPG20 in the limb buds and forebrain during embryogenesis may explain the developmental origin of the skeletal and cognitive defects observed in this disorder.

Published

2010

33. Diminished dosage of 22q11 genes disrupts neurogenesis and cortical development in a mouse model of 22q11 deletion/DiGeorge syndrome.

Author

Meechan DW, Tucker ES, Maynard TM, and LaMantia AS

Subjects

Animals, Cell Cycle Proteins genetics, Cell Differentiation, Cell Proliferation, Cerebral Cortex cytology, Cerebral Cortex embryology, Cyclin D1 genetics, DiGeorge Syndrome embryology, DiGeorge Syndrome pathology, Disease Models, Animal, Gene Expression Regulation, Developmental, Histones metabolism, Humans, Immunohistochemistry, Mice, Mice, Inbred C57BL, Mice, Knockout, Phosphoproteins metabolism, Reverse Transcriptase Polymerase Chain Reaction, Synteny, T-Box Domain Proteins genetics, Cerebral Cortex metabolism, Chromosome Deletion, Chromosomes, Human, Pair 21 genetics, Chromosomes, Mammalian genetics, DiGeorge Syndrome genetics

Abstract

The 22q11 deletion (or DiGeorge) syndrome (22q11DS), the result of a 1.5- to 3-megabase hemizygous deletion on human chromosome 22, results in dramatically increased susceptibility for "diseases of cortical connectivity" thought to arise during development, including schizophrenia and autism. We show that diminished dosage of the genes deleted in the 1.5-megabase 22q11 minimal critical deleted region in a mouse model of 22q11DS specifically compromises neurogenesis and subsequent differentiation in the cerebral cortex. Proliferation of basal, but not apical, progenitors is disrupted, and subsequently, the frequency of layer 2/3, but not layer 5/6, projection neurons is altered. This change is paralleled by aberrant distribution of parvalbumin-labeled interneurons in upper and lower cortical layers. Deletion of Tbx1 or Prodh (22q11 genes independently associated with 22q11DS phenotypes) does not similarly disrupt basal progenitors. However, expression analysis implicates additional 22q11 genes that are selectively expressed in cortical precursors. Thus, diminished 22q11 gene dosage disrupts cortical neurogenesis and interneuron migration. Such developmental disruption may alter cortical circuitry and establish vulnerability for developmental disorders, including schizophrenia and autism.

Published

2009

34. Mitochondrial localization and function of a subset of 22q11 deletion syndrome candidate genes.

Author

Maynard TM, Meechan DW, Dudevoir ML, Gopalakrishna D, Peters AZ, Heindel CC, Sugimoto TJ, Wu Y, Lieberman JA, and Lamantia AS

Subjects

Acyltransferases genetics, Acyltransferases metabolism, Animals, Brain cytology, Brain metabolism, Cells, Cultured, Computational Biology, Fibroblasts cytology, Fibroblasts physiology, Humans, Membrane Proteins genetics, Membrane Proteins metabolism, Mice, Mitochondria metabolism, Mitochondrial Proteins genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Synapses metabolism, Two-Hybrid System Techniques, Chromosome Deletion, Chromosomes, Human, Pair 22 genetics, DiGeorge Syndrome genetics, Mitochondria genetics, Mitochondrial Proteins metabolism

Abstract

Six genes in the 1.5 Mb region of chromosome 22 deleted in DiGeorge/22q11 deletion syndrome-Mrpl40, Prodh, Slc25a1, Txnrd2, T10, and Zdhhc8-encode mitochondrial proteins. All six genes are expressed in the brain, and maximal expression coincides with peak forebrain synaptogenesis shortly after birth. Furthermore, their protein products are associated with brain mitochondria, including those in synaptic terminals. Among the six, only Zddhc8 influences mitochondria-regulated apoptosis when overexpressed, and appears to interact biochemically with established mitochondrial proteins. Zdhhc8 has an apparent interaction with Uqcrc1, a component of mitochondrial complex III. The two proteins are coincidently expressed in pre-synaptic processes; however, Zdhhc8 is more frequently seen in glutamatergic terminals. 22q11 deletion may alter metabolic properties of cortical mitochondria during early post-natal life, since expression complex III components, including Uqcrc1, is significantly increased at birth in a mouse model of 22q11 deletion, and declines to normal values in adulthood. Our results suggest that altered dosage of one, or several 22q11 mitochondrial genes, particularly during early post-natal cortical development, may disrupt neuronal metabolism or synaptic signaling.

Published

2008

35. When half is not enough: gene expression and dosage in the 22q11 deletion syndrome.

Author

Meechan DW, Maynard TM, Gopalakrishna D, Wu Y, and LaMantia AS

Subjects

Aneuploidy, Animals, Gene Expression Regulation, Developmental, Humans, Mice, Models, Biological, Phenotype, DiGeorge Syndrome genetics, Gene Dosage physiology, Gene Expression

Abstract

The 22q11 Deletion Syndrome (22q11DS, also known as DiGeorge or Velo-Cardio-Facial Syndrome) has a variable constellation of phenotypes including life-threatening cardiac malformations, craniofacial, limb, and digit anomalies, a high incidence of learning, language, and behavioral disorders, and increased vulnerability for psychiatric diseases, including schizophrenia. There is still little clear understanding of how heterozygous microdeletion of approximately 30-50 genes on chromosome 22 leads to this diverse spectrum of phenotypes, especially in the brain. Three possibilities exist: 1) 22q11DS may reflect haploinsufficiency, homozygous loss of function, or heterozygous gain of function of a single gene within the deleted region; 2) 22q11DS may result from haploinsufficiency, homozygous loss of function, or heterozygous gain of function of a few genes in the deleted region acting at distinct phenotypically compromised sites; 3) 22q11DS may reflect combinatorial effects of reduced dosage of multiple genes acting in concert at all phenotypically compromised sites. Here, we consider evidence for each of these possibilities. Our review of the literature, as well as interpretation of work from our laboratory, favors the third possibility: 22q11DS reflects diminished expression of multiple 22q11 genes acting on common cellular processes during brain as well as heart, face, and limb development, and subsequently in the adolescent and adult brain.

Published

2007

36. Gene dosage in the developing and adult brain in a mouse model of 22q11 deletion syndrome.

Author

Meechan DW, Maynard TM, Wu Y, Gopalakrishna D, Lieberman JA, and LaMantia AS

Subjects

Age Factors, Animals, Animals, Newborn, Disease Models, Animal, Electrophoretic Mobility Shift Assay methods, Embryo, Mammalian, Humans, In Situ Hybridization methods, Mice, Mice, Inbred C57BL, Mice, Knockout, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction methods, Snail Family Transcription Factors, Syndrome, Transcription Factors genetics, Transcription Factors metabolism, Brain embryology, Brain growth & development, Brain pathology, Chromosome Deletion, DiGeorge Syndrome genetics, Gene Dosage, Gene Expression Regulation, Developmental genetics

Abstract

We evaluated the consequences of heterozygous chromosome 22q11 deletion - a significant genetic risk for schizophrenia - for expression levels and patterns of a subset of 22q11 genes implicated in schizophrenia and other phenotypes in mouse models of 22q11 deletion syndrome (22q11DS). In deleted embryos, expression levels of at least nine 22q11 orthologues decline by 40-60% in the frontonasal mass/forebrain and other 22q11DS phenotypic sites (branchial and aortic arches, limb buds); however, coincident expression patterns of 22q11 and Snail genes - diagnostic for neural crest-derived mesenchyme - are unchanged, and Snail1 expression levels do not decline. Subsequently, 22q11 mRNA levels are reduced by 40-60% in the brains of developing, adolescent and adult deleted mice without altered expression patterns, dysmorphology or reduced cell density. Apparently, in deleted individuals, 22q11 gene expression declines across otherwise stable cell populations, perhaps disrupting individual cell function via diminished dosage. Such changes might contribute to schizophrenia vulnerability in 22q11DS.

Published

2006

37. No evidence for parental imprinting of mouse 22q11 gene orthologs.

Author

Maynard TM, Meechan DW, Heindel CC, Peters AZ, Hamer RM, Lieberman JA, and LaMantia AS

Subjects

Alleles, Animals, Crosses, Genetic, Female, Gene Deletion, Gene Expression, Gene Silencing, Male, Mice, Mice, Inbred C57BL, Polymorphism, Single Nucleotide, Sequence Homology, DiGeorge Syndrome genetics, Genomic Imprinting genetics

Abstract

Non-Mendelian factors may influence central nervous system (CNS) phenotypes in patients with 22q11 Deletion Syndrome (22q11DS, also known as DiGeorge or Velocardiofacial Syndrome), and similar mechanisms may operate in mice carrying a deletion of one or more 22q11 gene orthologs. Accordingly, we examined the influence of parent of origin on expression of 25 murine 22q11 orthologs in the developing and mature CNS using single nucleotide polymorphism (SNP)-based analysis in interspecific crosses and quantification of mRNA in a murine model of 22q11DS. We found no evidence for absolute genomic imprinting or silencing. All 25 genes are biallelically expressed in the developing and adult brains. Furthermore, if more subtle forms of allelic biasing are present, they are very small in magnitude and most likely beyond the resolution of currently available quantitative approaches. Given the high degree of similarity of human 22q11 and the orthologous region of mmChr16, genomic imprinting most likely cannot explain apparent parent-of-origin effects in 22q11DS.

Published

2006

38. Limited influence of olanzapine on adult forebrain neural precursors in vitro.

Author

Councill JH, Tucker ES, Haskell GT, Maynard TM, Meechan DW, Hamer RM, Lieberman JA, and LaMantia AS

Subjects

Animals, Benzodiazepines pharmacology, Bromodeoxyuridine metabolism, Cerebral Ventricles cytology, Cerebral Ventricles drug effects, Dose-Response Relationship, Drug, Gene Expression drug effects, Immunohistochemistry methods, In Vitro Techniques, Mice, Nerve Tissue Proteins metabolism, Neurons physiology, Olanzapine, RNA, Messenger biosynthesis, Reverse Transcriptase Polymerase Chain Reaction methods, Stem Cells physiology, Neurons drug effects, Prosencephalon cytology, Selective Serotonin Reuptake Inhibitors pharmacology, Stem Cells drug effects

Abstract

We evaluated the activity of the atypical antipsychotic drug olanzapine on differentiation and gene expression in adult neural precursor cells in vitro. Neural precursors obtained from forebrain subventricular zone (SVZ)-derived neurospheres express a subset (13/24) of receptors known to bind olanzapine at high to intermediate affinities; in contrast, all 24 are expressed in the SVZ. In the presence of 10 nM, 100 nM or 1 microM olanzapine, there is no significant change in the frequency of oligodendrocytes, neurons, GABAergic neurons and astrocytes generated from neurosphere precursors. In parallel, there is no apparent change in cell proliferation in response to olanzapine, based upon bromodeoxyuridine incorporation. There are no major changes in cytological differentiation in response to the drug; however, at one concentration (10 nM) there is a small but statistically significant increase in the size of glial fibrillary acidic protein-labeled astrocytes derived from neurosphere precursors. In addition, olanzapine apparently modulates expression of one serotonin receptor -- 5HT2A -- in differentiating neurosphere cultures; however, it does not modify expression of several other receptors or schizophrenia vulnerability genes. Thus, olanzapine has a limited influence on differentiation and gene expression in adult neural precursor cells in vitro.

Published

2006

39. A comprehensive analysis of 22q11 gene expression in the developing and adult brain.

Author

Maynard TM, Haskell GT, Peters AZ, Sikich L, Lieberman JA, and LaMantia AS

Subjects

Abnormalities, Multiple genetics, Adolescent, Adult, Aged, Animals, Brain embryology, Child, Chromosome Deletion, Cognition Disorders genetics, Craniofacial Abnormalities genetics, Gene Expression, Gene Expression Profiling, Heart Defects, Congenital genetics, Humans, Limb Deformities, Congenital genetics, Male, Mice, Mice, Inbred ICR, Mice, Knockout, Middle Aged, Oligonucleotide Array Sequence Analysis, Rats, Schizophrenia genetics, Syndrome, Brain growth & development, Brain metabolism, Chromosomes, Human, Pair 22 genetics

Abstract

Deletions at 22q11.2 are linked to DiGeorge or velocardiofacial syndrome (VCFS), whose hallmarks include heart, limb, and craniofacial anomalies, as well as learning disabilities and increased incidence of schizophrenia. To assess the potential contribution of 22q11 genes to cognitive and psychiatric phenotypes, we determined the CNS expression of 32 mouse orthologs of 22q11 genes, primarily in the 1.5-Mb minimal critical region consistently deleted in VCFS. None are uniquely expressed in the developing or adult mouse brain. Instead, 27 are localized in the embryonic forebrain as well as aortic arches, branchial arches, and limb buds. Each continues to be expressed at apparently constant levels in the fetal, postnatal, and adult brain, except for Tbx1, ProDH2, and T10, which increase in adolescence and decline in maturity. At least six 22q11 proteins are seen primarily in subsets of neurons, including some in forebrain regions thought to be altered in schizophrenia. Thus, 22q11 deletion may disrupt expression of multiple genes during development and maturation of neurons and circuits compromised by cognitive and psychiatric disorders associated with VCFS.

Published

2003

40. Mesenchymal/epithelial regulation of retinoic acid signaling in the olfactory placode.

Author

Bhasin N, Maynard TM, Gallagher PA, and LaMantia AS

Subjects

Aldehyde Oxidoreductases genetics, Animals, Culture Techniques, Epithelium embryology, Epithelium physiology, Fibroblast Growth Factor 8, Fibroblast Growth Factors genetics, Gene Expression Regulation, Developmental, In Situ Hybridization, Mesoderm cytology, Mesoderm physiology, Mice, Mice, Inbred ICR, Mice, Transgenic, Neural Crest embryology, Neural Crest physiology, Olfactory Pathways physiology, Receptors, Retinoic Acid genetics, Signal Transduction, Olfactory Pathways embryology, Tretinoin physiology

Abstract

We asked whether mesenchymal/epithelial (M/E) interactions regulate retinoic acid (RA) signaling in the olfactory placode and whether this regulation is similar to that at other sites of induction, including the limbs, branchial arches, and heart. RA is produced by the mesenchyme at all sites, and subsets of mesenchymal cells express the RA synthetic enzyme RALDH2, independent of M/E interactions. In the placode, RA-producing mesenchyme is further distinguished by its coincidence with a molecularly distinct population of neural crest-associated cells. At all sites, expression of additional RA signaling molecules (RARalpha, RARbeta, RXR, CRABP1) depends on M/E interactions. Of these molecules, RA regulates only RARbeta, and this regulation depends on M/E interaction. Expression of Fgf8, shh, and Bmp4, all of which are thought to influence RA signaling, is also regulated by M/E interactions independent of RA at all sites. Despite these common features, RALDH3 expression is distinct in the placode, as is regulation of RARbeta and RALDH2 by Fgf8. Thus, M/E interactions regulate expression of RA receptors and cofactors in the olfactory placode and other inductive sites. Some aspects of regulation in the placode are distinct, perhaps reflecting unique roles for additional local signals in neuronal differentiation in the developing olfactory pathway.

Published

2003

41. Retinoic acid signaling at sites of plasticity in the mature central nervous system.

Author

Thompson Haskell G, Maynard TM, Shatzmiller RA, and Lamantia AS

Subjects

Aldehyde Oxidoreductases biosynthesis, Aldehyde Oxidoreductases genetics, Animals, Calbindin 2, Calbindins, Gene Expression Regulation, Genes, Reporter, Male, Mice, Mice, Transgenic, Neurons metabolism, Olfactory Bulb cytology, Proto-Oncogene Proteins c-fos biosynthesis, Proto-Oncogene Proteins c-fos genetics, Receptors, Retinoic Acid biosynthesis, Receptors, Retinoic Acid genetics, Retinal Dehydrogenase, Retinoic Acid Receptor alpha, Retinoid X Receptors, S100 Calcium Binding Protein G biosynthesis, S100 Calcium Binding Protein G genetics, Spinal Cord cytology, Transcription Factors biosynthesis, Transcription Factors genetics, Neuronal Plasticity genetics, Olfactory Bulb metabolism, Signal Transduction genetics, Spinal Cord metabolism, Tretinoin metabolism

Abstract

We used transgenic reporter mice to determine whether brain regions that respond to retinoic acid (RA) during development do so in maturity. We focused on two prominent sites of embryonic RA signaling: the dorsal spinal cord and the olfactory bulb. In the mature dorsal spinal cord, expression of a direct repeat 5 RA response element (DR5-RARE) transgene is seen in interneurons in laminae I and II, as well as in ependymal cells around the central canal. In the olfactory bulb, DR5-RARE transgene-expressing neurons are seen in the mature granule cell and periglomerular layers, as well as in cells in the subventricular zone of the forebrain-the established source for newly generated granule and periglomerular neurons. In addition, there are transgene-labeled neurons in a small number of other brain regions. These include the spinal trigeminal nucleus, area postrema, habenula, amygdala, and the cerebral cortex. Thus, a distinct type of RA-mediated gene expression, detected with the DR5-RARE reporter transgene, defines neurons, subependymal, or ependymal cells in discrete locations throughout the neuraxis. Some of these cells--particularly those in the spinal cord and olfactory bulb--are found in central nervous system regions that receive local RA signals early in development, and retain a significant amount of functional or structural plasticity in the adult., (Copyright 2002 Wiley-Liss, Inc.)

Published

2002

42. 22q11 DS: genomic mechanisms and gene function in DiGeorge/velocardiofacial syndrome.

Author

Maynard TM, Haskell GT, Lieberman JA, and LaMantia AS

Subjects

Animals, Central Nervous System embryology, Central Nervous System growth & development, Central Nervous System physiopathology, Child, Chromosome Mapping, Depressive Disorder, Major metabolism, Depressive Disorder, Major physiopathology, Developmental Disabilities metabolism, Developmental Disabilities physiopathology, Gene Expression Regulation, Developmental genetics, Genome, Humans, Schizophrenia metabolism, Schizophrenia physiopathology, Chromosomes, Human, Pair 22 genetics, Depressive Disorder, Major genetics, Developmental Disabilities genetics, DiGeorge Syndrome complications, DiGeorge Syndrome genetics, Mutation genetics, Schizophrenia genetics

Abstract

22q11 deletion syndrome (22qDS), also known as DiGeorge or velocardiofacial syndrome (DGS/VCFS), is a relatively common genetic anomaly that results in malformations of the heart, face and limbs. In addition, patients with 22qDS are at significant risk for psychiatric disorders as well, with one in four developing schizophrenia, and one in six developing major depressive disorders. Like several other deletion syndromes associated with psychiatric or cognitive problems, it has been difficult to determine which of the specific genes in this genomic region may mediate the syndrome. For example, patients with different genomic deletions within the 22q11 region have been found that have similar phenotypes, even though their deletions do not compromise the same set of genes. In this review, we discuss the individual genes found in the region of 22q11 that is commonly deleted in 22qDS patients, and the potential roles each of these genes may play in the syndrome. Although many of these genes are interesting candidates by themselves, we hypothesize that the full spectrum of anomalies associated with 22qDS may result from the combined result of disruptions to numerous genes within the region that are involved in similar developmental or cellular processes.

Published

2002

43. RanBP1, a velocardiofacial/DiGeorge syndrome candidate gene, is expressed at sites of mesenchymal/epithelial induction.

Author

Maynard TM, Haskell GT, Bhasin N, Lee JM, Gassman AA, Lieberman JA, and LaMantia AS

Subjects

Animals, Aorta embryology, DiGeorge Syndrome genetics, Embryonic Induction genetics, Female, Gene Expression Regulation, Developmental, Humans, Limb Buds, Mice, Mice, Inbred ICR, Nuclear Proteins metabolism, ran GTP-Binding Protein metabolism, Epithelium embryology, Mesoderm, Nuclear Proteins genetics, ran GTP-Binding Protein genetics

Abstract

RanBP1, a velocardiofacial syndrome/DiGeorge syndrome candidate gene, is expressed in the frontonasal processes, branchial arches, aortic arches, and limb buds. At these sites, RanBP1 apparently coincides with neural crest-derived mesenchymal cells. In addition, RanBP1 is expressed in the forebrain as well as in hindbrain regions previously associated with crest-derived mesenchymal cells.

Published

2002

44. High-resolution mapping of the Gli3 mutation extra-toes reveals a 51.5-kb deletion.

Author

Maynard TM, Jain MD, Balmer CW, and LaMantia AS

Subjects

Animals, Base Sequence, DNA, Complementary analysis, Forelimb abnormalities, Hindlimb abnormalities, Humans, Kruppel-Like Transcription Factors, Mice, Molecular Sequence Data, Sequence Homology, Zinc Finger Protein Gli3, Chromosome Deletion, Contig Mapping methods, DNA-Binding Proteins genetics, Mutation, Nerve Tissue Proteins, Repressor Proteins, Toes abnormalities, Transcription Factors genetics, Xenopus Proteins

Published

2002

45. Neural development, cell-cell signaling, and the "two-hit" hypothesis of schizophrenia.

Author

Maynard TM, Sikich L, Lieberman JA, and LaMantia AS

Subjects

Chromosome Deletion, Chromosomes, Human, Pair 22 genetics, Environment, Humans, Neural Pathways abnormalities, Neural Pathways pathology, Neural Pathways physiopathology, Tretinoin adverse effects, Brain abnormalities, Brain pathology, Brain physiopathology, Cell Communication physiology, Psychological Theory, Schizophrenia etiology, Schizophrenia pathology, Schizophrenia physiopathology

Abstract

To account for the complex genetics, the developmental biology, and the late adolescent/early adulthood onset of schizophrenia, the "two-hit" hypothesis has gained increasing attention. In this model, genetic or environmental factors disrupt early central nervous system (CNS) development. These early disruptions produce long-term vulnerability to a "second hit" that then leads to the onset of schizophrenia symptoms. The cell-cell signaling pathways involved in nonaxial induction, morphogenesis, and differentiation in the brain, as well as in the limbs and face, could be targets for a "first hit" during early development. These same pathways, redeployed for neuronal maintenance rather than morphogenesis, may be targets for a "second hit" in the adolescent or adult brain. Furthermore, dysregulation of cell-cell signaling by a "first hit" may prime the CNS for a pathologic response to a "second hit" via the same signaling pathway. Thus, parallel disruption of cell-cell signaling in both the developing and the mature CNS provides a plausible way of integrating genetic, developmental, and environmental factors that contribute to vulnerability and pathogenesis in schizophrenia.

Published

2001

46. Cell interactions within nascent neural crest cell populations transiently promote death of neurogenic precursors.

Author

Maynard TM, Wakamatsu Y, and Weston JA

Subjects

Amino Acid Chloromethyl Ketones pharmacology, Animals, Apoptosis drug effects, Cell Communication, Cell Death, Cell Differentiation, Cells, Cultured, Cellular Senescence, Cysteine Proteinase Inhibitors pharmacology, Embryo, Nonmammalian, Homeodomain Proteins physiology, Intracellular Signaling Peptides and Proteins, Kinetics, Membrane Proteins genetics, Membrane Proteins physiology, Neural Crest cytology, Neurons drug effects, Quail, Tretinoin pharmacology, Apoptosis physiology, Neural Crest physiology, Neurons cytology, Neurons physiology

Abstract

We have previously shown that cultured trunk neural crest cell populations irreversibly lose neurogenic ability when dispersal is prevented or delayed, while the ability to produce other crest derivatives is retained (Vogel, K. S. and Weston, J. A. (1988) Neuron 1, 569-577). Here, we show that when crest cells are prevented from dispersing, cell death is increased and neurogenesis is decreased in the population, as a result of high cell density. Control experiments to characterize the effects of high cell density on environmental conditions in culture suggest that reduced neurogenesis is the result of cell-cell interactions and not changes (conditioning or depletion) of the culture medium. Additionally, we show that the caspase inhibitor zVAD-fmk, which blocks developmentally regulated cell death, rescues the neurogenic ability of high density cultures, without any apparent effect on normal, low-density cultures. We conclude, therefore, that increased cell interaction at high cell densities results in the selective death of neurogenic precursors in the nascent crest population. Furthermore, we show that neurogenic cells in cultured crest cell populations that have dispersed immediately are not susceptible to contact-mediated death, even if they are subsequently cultured at high cell density. Since most early migrating avian crest cells express Notch1, and a subset expresses Delta1 (Wakamatsu, Y., Maynard, T. M. and Weston, J. A. (2000) Development 127, 2811-2821), we tested the possibility that the effects of cell contact were mediated by components of a Notch signaling pathway. We found that neurogenic precursors are eliminated when crest cells are co-cultured with exogenous Delta1-expressing cells immediately after they segregate from the neural tube, although not after they have previously dispersed. We conclude that early and prolonged cell interactions, mediated at least in part by Notch signaling, can regulate the survival of neurogenic cells within the nascent crest population. We suggest that a transient episode of cell contact-mediated death of neurogenic cells may serve to eliminate fate-restricted neurogenic cells that fail to disperse promptly in vivo.

Published

2000

47. Fate determination of neural crest cells by NOTCH-mediated lateral inhibition and asymmetrical cell division during gangliogenesis.

Author

Wakamatsu Y, Maynard TM, and Weston JA

Subjects

Animals, Bromodeoxyuridine metabolism, Cell Differentiation, Cell Division, Cell Lineage, Cell Movement, Cells, Cultured, Chick Embryo, Cloning, Molecular, Coturnix embryology, Drosophila Proteins, Ganglia cytology, Ganglia, Spinal embryology, Ganglia, Spinal metabolism, In Situ Hybridization, Intracellular Signaling Peptides and Proteins, Juvenile Hormones biosynthesis, Membrane Proteins biosynthesis, Mitosis, Neuroglia cytology, Neurons physiology, Receptors, Notch, Signal Transduction, Time Factors, Transfection, Ganglia embryology, Membrane Proteins metabolism, Neural Crest embryology

Abstract

Avian trunk neural crest cells give rise to a variety of cell types including neurons and satellite glial cells in peripheral ganglia. It is widely assumed that crest cell fate is regulated by environmental cues from surrounding embryonic tissues. However, it is not clear how such environmental cues could cause both neurons and glial cells to differentiate from crest-derived precursors in the same ganglionic locations. To elucidate this issue, we have examined expression and function of components of the NOTCH signaling pathway in early crest cells and in avian dorsal root ganglia. We have found that Delta1, which encodes a NOTCH ligand, is expressed in early crest-derived neuronal cells, and that NOTCH1 activation in crest cells prevents neuronal differentiation and permits glial differentiation in vitro. We also found that NUMB, a NOTCH antagonist, is asymmetrically segregated when some undifferentiated crest-derived cells in nascent dorsal root ganglia undergo mitosis. We conclude that neuron-glia fate determination of crest cells is regulated, at least in part, by NOTCH-mediated lateral inhibition among crest-derived cells, and by asymmetric cell division.

Published

2000

48. Avian transitin expression mirrors glial cell fate restrictions during neural crest development.

Author

Henion PD, Blyss GK, Luo R, An M, Maynard TM, Cole GJ, and Weston JA

Subjects

Animals, Antibodies, Monoclonal, Cell Differentiation physiology, Cell Movement physiology, Cells, Cultured, Chick Embryo, Ganglia, Spinal cytology, Gene Expression Regulation, Developmental physiology, Glial Fibrillary Acidic Protein analysis, Glial Fibrillary Acidic Protein immunology, Hybridomas, Intermediate Filament Proteins, Melanocytes cytology, Mice, Nerve Tissue Proteins analysis, Nerve Tissue Proteins immunology, Nestin, Neuroglia chemistry, Neurons chemistry, Neurons cytology, Neurons physiology, Quail, Stem Cells chemistry, Stem Cells cytology, Stem Cells physiology, Glial Fibrillary Acidic Protein genetics, Nerve Tissue Proteins genetics, Neural Crest cytology, Neural Crest embryology, Neuroglia cytology, Neuroglia physiology

Abstract

During development, trunk neural crest cells give rise to three primary classes of derivatives: glial cells, melanocytes, and neurons. As part of an effort to learn how neural crest diversification is regulated, we have produced monoclonal antibodies (MAbs) that recognize antigens expressed by neural crest cells early in development. One of these, MAb 7B3 (7B3), was found to recognize an avian transitin-like protein by co-immunostaining with a series of transitin-specific monoclonal antibodies and by Western blot analysis. In neural crest cell cultures, we found that 7B3 initially recognizes the majority of neural crest cells as they emerge from the neural tube. Subsequently, 7B3-immunoreactivity (IR) is progressively restricted to a smaller subpopulation of cells. In fully differentiated trunk neural crest cell cultures, 7B3-IR is expressed only by cells that do not express neuronal markers and lack melanin granules. During development in vivo, 7B3-IR is evident in neural crest cells on the medial, but not the lateral migration pathway, suggesting that it is not expressed by melanocyte precursors. Later, the antigen is detected in non-neuronal, presumptive glial cells in dorsal root ganglia (DRG) and sympathetic ganglia, as well as along ventral roots. Cultures of E5 DRG confirm that 7B3-IR is restricted to non-neuronal cells of ganglia, many of which closely associate with neuronal processes. Therefore, of the three major classes of differentiated trunk neural crest derivatives, 7B3 exclusively recognizes glial cells, including both satellite glia and Schwann cells. Since the pattern of 7B3 expression in vitro mirrors the pattern of glial cell fate-restrictions in the trunk neural crest lineage, and is expressed by neural crest-derived glia in vivo, we conclude that 7B3 is an early pan-glial marker for neural crest-derived glial cells and their precursors.

Published

2000

49. NUMB localizes in the basal cortex of mitotic avian neuroepithelial cells and modulates neuronal differentiation by binding to NOTCH-1.

Author

Wakamatsu Y, Maynard TM, Jones SU, and Weston JA

Subjects

Amino Acid Sequence genetics, Animals, Cell Differentiation physiology, Cerebral Cortex cytology, Cerebral Cortex metabolism, Chick Embryo cytology, Chick Embryo physiology, Chickens genetics, Cloning, Molecular, Coturnix metabolism, Drosophila Proteins, Embryo, Nonmammalian cytology, Embryo, Nonmammalian metabolism, Embryo, Nonmammalian physiology, Epithelial Cells metabolism, Juvenile Hormones genetics, Membrane Proteins physiology, Mice, Molecular Sequence Data, Receptor, Notch1, Sequence Homology, Amino Acid, Signal Transduction physiology, Tissue Distribution physiology, Cerebral Cortex embryology, Chick Embryo metabolism, Coturnix embryology, Juvenile Hormones metabolism, Membrane Proteins metabolism, Neurons cytology, Receptors, Cell Surface, Transcription Factors

Abstract

The importance of lateral inhibition mediated by NOTCH signaling is well demonstrated to control neurogenesis both in invertebrates and vertebrates. We have identified the chicken homolog of Drosophila numb, which suppresses NOTCH signaling. We show that chicken NUMB (c-NUMB) protein is localized to the basal cortex of mitotic neuroepithelial cells, suggesting that c-NUMB regulates neurogenesis by the modification of NOTCH signaling through asymmetrical cell division. Consistent with this suggestion, we show (1) that c-NUMB interferes with the nuclear translocation of activated c-NOTCH-1 through direct binding to the PEST sequence in the cytoplasmic domain of c-NOTCH-1 and (2) that c-NUMB interferes with c-NOTCH-1-mediated inhibition of neuronal differentiation.

Published

1999

50. Glial domains and axonal reordering in the chiasmatic region of the developing ferret.

Author

Reese BE, Maynard TM, and Hocking DR

Subjects

Animals, Axons chemistry, Embryonic and Fetal Development physiology, Ferrets embryology, Ferrets metabolism, Glial Fibrillary Acidic Protein analysis, Immunohistochemistry, Neuroglia chemistry, Optic Chiasm chemistry, Vimentin analysis, Axons ultrastructure, Ferrets anatomy & histology, Neuroglia ultrastructure, Optic Chiasm ultrastructure

Abstract

This study has examined the developing glial architecture of the optic pathway and has related this to the changing organization of the constituent axons. Immunocytochemistry was used to reveal the distribution of glial profiles, and DiI was used to label either radial glial profiles or optic axons. Electron microscopy was used to determine the distribution of glial profiles, axons, growth cones, and wrists at different locations along the pathway. Three different glial boundaries were defined: Two of these are revealed as changes in the distribution of vimentin-immunoreactive profiles occurring in the prechiasmatic optic nerve and at the threshold of the optic tract, respectively, and one by the presence of glial fibrillary acidic protein (GFAP)-immunoreactive profiles at the chiasmatic midline. The latter, midline boundary may be related to the segregation of nasal from temporal optic axons. The boundary at the threshold of the optic tract coincides with the segregation of dorsal from ventral optic axons that emerges at this location in the pathway. The segregation of old from young optic axons is shown to occur only gradually along the pathway. Glial profiles are most frequent in the deeper parts of the tract, coursing parallel to the optic axons and orthogonal to their usual radial axis. These are suggested to arise from later-growing radial glial fibers that are diverted to grow amongst the older optic axons. Those glial profiles may subsequently impede axonal invasion, thus creating the chronotopic reordering by forcing the later-arriving axons to accumulate superficially.

Published

1994