Reconstitution of mouse inner ear sensory development from pluripotent stem cells

Koehler, Karl R.

01 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The inner ear contains specialized sensory epithelia that detect head movements, gravity and sound. Hearing loss and imbalance are primarily caused by degeneration of the mechanosensitive hair cells in sensory epithelia or the sensory neurons that connect the inner ear to the brain. The controlled derivation of inner ear sensory epithelia and neurons from pluripotent stem cells will be essential for generating in vitro models of inner ear disorders or developing cell-based therapies. Despite some recent success in deriving hair cells from mouse embryonic stem (ES) cells, it is currently unclear how to derive inner ear sensory cells in a fully defined and reproducible manner. Progress has likely been hindered by what is known about induction of the nonneural and preplacodal ectoderm, two critical precursors during inner ear development. The studies presented here report the step-wise differentiation of inner ear sensory epithelia from mouse ES cells in three-dimensional culture. We show that nonneural, preplacodal and pre-otic epithelia can be generated from ES cell aggregates by precise temporal control of BMP, TGFβ and FGF signaling, mimicking in vivo development. Later, in a self-guided process, vesicles containing supporting cells emerge from the presumptive otic epithelium and give rise to hair cells with stereocilia bundles and kinocilium. Remarkably, the vesicles developed into large cysts with sensory epithelia reminiscent of vestibular sense organs (i.e. the utricle, saccule and crista), which sense head movements and gravity in the animal. We have designated these stem cell-derived structures inner ear organoids. In addition, we discovered that sensory-like neurons develop alongside the organoids and form putative synapses with hair cells in a similar fashion to the hair cell-to-neuron circuit that forms in the developing embryo. Our data thus establish a novel in vitro model of inner ear organogenesis that can be used to gain deeper insight into inner ear development and disorder.

Inner ear

Pluripotent stem cells

Hair cells

Labyrinth (Ear) -- Cytology

Labyrinth (Ear) -- Cytopathology

Labyrinth (Ear) -- Pathophysiology

Labyrinth (Ear) -- Research

Labyrinth (Ear) -- Diseases -- Treatment

Epithelial cells

Deafness

Cellular therapy

Cochlea -- Pathophysiology

Hearing disorders

Multipotent stem cells

Embryonic stem cells

Cell differentiation

Mice as laboratory animals

Shp2 deletion in post-migratory neural crest cells results in impaired cardiac sympathetic innervation

Lajiness, Jacquelyn D.

January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Autonomic innervation of the heart begins in utero and continues during the neonatal phase of life. A balance between the sympathetic and parasympathetic arms of the autonomic nervous system is required to regulate heart rate as well as the force of each contraction. Our lab studies the development of sympathetic innervation of the early postnatal heart in a conditional knockout (cKO) of Src homology protein tyrosine phosphatase 2 (Shp2). Shp2 is a ubiquitously expressed non-receptor phosphatase involved in a variety of cellular functions including survival, proliferation, and differentiation. We targeted Shp2 in post-migratory neural crest (NC) lineages using our novel Periostin-Cre. This resulted in a fully penetrant mouse model of diminished cardiac sympathetic innervation and concomitant bradycardia that progressively worsen. Shp2 is thought to mediate its basic cellular functions through a plethora of signaling cascades including extracellular signal-regulated kinases (ERK) 1 and 2. We hypothesize that abrogation of downstream ERK1/2 signaling in NC lineages is primarily responsible for the failed sympathetic innervation phenotype observed in our mouse model. Shp2 cKOs are indistinguishable from control littermates at birth and exhibit no gross structural cardiac anomalies; however, in vivo electrocardiogram (ECG) characterization revealed sinus bradycardia that develops as the Shp2 cKO ages. Significantly, 100% of Shp2 cKOs die within 3 weeks after birth. Characterization of the expression pattern of the sympathetic nerve marker tyrosine hydroxylase (TH) revealed a loss of functional sympathetic ganglionic neurons and reduction of cardiac sympathetic axon density in Shp2 cKOs. Shp2 cKOs exhibit lineage-specific suppression of activated pERK1/2 signaling, but not of other downstream targets of Shp2 such as pAKT (phosphorylated-Protein kinase B). Interestingly, restoration of pERK signaling via lineage-specific expression of constitutively active MEK1 (Mitogen-activated protein kinase kinase1) rescued TH-positive cardiac innervation as well as heart rate. These data suggest that the diminished sympathetic cardiac innervation and the resulting ECG abnormalities are a result of decreased pERK signaling in post-migratory NC lineages.

Cardiac development

Sympathetic innervation

Shp2

pERK

Bradycardia

Heart -- Diseases

Autonomic nervous system -- Physiology

Heart -- Growth

Sympathetic nervous system

Protein-tyrosine phosphatase

Heart conduction system

Heart -- Diseases -- Treatment

Protein kinases

Developmental neurobiology -- Research

Heart rate monitoring

Neural crest -- Research

Bradycardia -- Etiology

Mice -- Diseases -- Molecular aspects

Pluripotency Factors Determine Gene Expression Repertoire at Zygotic Genome Activation

Gao, Meijiang, Veil, Marina, Rosenblatt, Marcus, Riesle, Aileen J., Gebhard, Anna, Hass, Helge, Buryanova, Lenka, Yampolsky, Lev Y., Grüning, Björn, Ulianov, Sergey V., Timmer, Jens, Onichtchouk, Daria

10 February 2022

Awakening of zygotic transcription in animal embryos relies on maternal pioneer transcription factors. The interplay of global and specific functions of these proteins remains poorly understood. Here, we analyze chromatin accessibility and time-resolved transcription in single and double mutant zebrafish embryos lacking pluripotency factors Pou5f3 and Sox19b. We show that two factors modify chromatin in a largely independent manner. We distinguish four types of direct enhancers by differential requirements for Pou5f3 or Sox19b. We demonstrate that changes in chromatin accessibility of enhancers underlie the changes in zygotic expression repertoire in the double mutants. Pou5f3 or Sox19b promote chromatin accessibility of enhancers linked to the genes involved in gastrulation and ventral fate specification. The genes regulating mesendodermal and dorsal fates are primed for activation independently of Pou5f3 and Sox19b. Strikingly, simultaneous loss of Pou5f3 and Sox19b leads to premature expression of genes, involved in regulation of organogenesis and differentiation.

animals

cell differentiation

chromatin (metabolism)

female

gastrulation

gene expression regulation

developmental

genome

male

SOX transcription factors (genetics)

transcription factors (metabolism)

zebrafish (genetics

growth & development

metabolism)

zebrafish proteins (genetics

metabolism)

zygote (growth & development

metabolism)

Biological Sciences

Understanding the Pathogenic Nature of L359V Variant of GATA-2 with Respect to Chronic Myeloid Leukemia.

Nadwodney, Martin Aleksander

January 2022

No description available.

Bioinformatics

Biochemistry

Computer Science

Oncology

Bioinformatics

Cell Differentiation

Cell Proliferation

Chronic Myeloid Leukemia

CML

ClinVar

ConSurf

GATA-2

GATA-2 Variant

GATA-2 Variants

I-TASSER

L359V

L359V variant

RaptorX

STRING

Xavier Protocol

Xavier Protocol Pie Chart

YASARA

Zinc Finger 2

ZF-2

Early events leading to the host protective Th2 immune response to an intestinal nematode parasite /

Pesce, John Thomas.

January 2005

Thesis (Ph. D.)--Uniformed Services University of the Health Sciences, 2005. / Typescript (photocopy).

Analysis and Reconstruction of the Hematopoietic Stem Cell Differentiation Tree: A Linear Programming Approach for Gene Selection

Ghadie, Mohamed A.

January 2015

Stem cells differentiate through an organized hierarchy of intermediate cell types to terminally differentiated cell types. This process is largely guided by master transcriptional regulators, but it also depends on the expression of many other types of genes. The discrete cell types in the differentiation hierarchy are often identified based on the expression or non-expression of certain marker genes. Historically, these have often been various cell-surface proteins, which are fairly easy to assay biochemically but are not necessarily causative of the cell type, in the sense of being master transcriptional regulators. This raises important questions about how gene expression across the whole genome controls or reflects cell state, and in particular, differentiation hierarchies. Traditional approaches to understanding gene expression patterns across multiple conditions, such as principal components analysis or K-means clustering, can group cell types based on gene expression, but they do so without knowledge of the differentiation hierarchy. Hierarchical clustering and maximization of parsimony can organize the cell types into a tree, but in general this tree is different from the differentiation hierarchy. Using hematopoietic differentiation as an example, we demonstrate how many genes other than marker genes are able to discriminate between different branches of the differentiation tree by proposing two models for detecting genes that are up-regulated or down-regulated in distinct lineages. We then propose a novel approach to solving the following problem: Given the differentiation hierarchy and gene expression data at each node, construct a weighted Euclidean distance metric such that the minimum spanning tree with respect to that metric is precisely the given differentiation hierarchy. We provide a set of linear constraints that are provably sufficient for the desired construction and a linear programming framework to identify sparse sets of weights, effectively identifying genes that are most relevant for discriminating different parts of the tree. We apply our method to microarray gene expression data describing 38 cell types in the hematopoiesis hierarchy, constructing a sparse weighted Euclidean metric that uses just 175 genes. These 175 genes are different than the marker genes that were used to identify the 38 cell types, hence offering a novel alternative way of discriminating different branches of the tree. A DAVID functional annotation analysis shows that the 175 genes reflect major processes and pathways active in different parts of the tree. However, we find that there are many alternative sets of weights that satisfy the linear constraints. Thus, in the style of random-forest training, we also construct metrics based on random subsets of the genes and compare them to the metric of 175 genes. Our results show that the 175 genes frequently appear in the random metrics, implicating their significance from an empirical point of view as well. Finally, we show how our linear programming method is able to identify columns that were selected to build minimum spanning trees on the nodes of random variable-size matrices.

Linear Programming

Distance Metric Learning

Machine Learning

Feature Selection

Tree Reconstruction

Hierarchical Clustering

Minimum Spanning Tree

Clustering

Optimization

Maximum Parsimony

Euclidean Distance

Weighted Euclidean

Stem Cell Differentiation

Hematopoiesis

Transcriptional Regulation

Transcription Factor

Gene Selection

Gene Expression

Microarray

Cell Type

Marker Gene

Functional Annotation

Random Forest

Biological Function

Regulation

Statistical Significance

Erythropoiesis

Natural Killer Cell

T Cell

B Cell

Granulocyte

Monocyte

Megakaryocyte

Minimization

Linear Constraint

Cell Lineage

Differentiation and characterization of cell types associated with retinal degenerative diseases using human induced pluripotent stem cells

Gupta, Manav

31 July 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Human induced pluripotent stem (iPS) cells have the unique ability to differentiate into 200 or so somatic cell types that make up the adult human being. The use of human iPS cells to study development and disease is a highly exciting and interdependent field that holds great promise in understanding and elucidating mechanisms behind cellular differentiation with future applications in drug screening and cell replacement studies for complex and currently incurable cellular degenerative disorders. The recent advent of iPS cell technology allows for the generation of patient-specific cell lines that enable us to model the progression of a disease phenotype in a human in vitro model. Differentiation of iPS cells toward the affected cell type provides an unlimited source of diseased cells for examination, and to further study the developmental progression of the disease in vitro, also called the “disease-in-a-dish” model. In this study, efforts were undertaken to recapitulate the differentiation of distinct retinal cell affected in two highly prevalent retinal diseases, Usher syndrome and glaucoma. Using a line of Type III Usher Syndrome patient derived iPS cells efforts were undertaken to develop such an approach as an effective in vitro model for studies of Usher Syndrome, the most commonly inherited disorder affecting both vision and hearing. Using existing lines of iPS cells, studies were also aimed at differentiation and characterization of the more complex retinal cell types, retinal ganglion cells (RGCs) and astrocytes, the cell types affected in glaucoma, a severe neurodegenerative disease of the retina leading to eventual irreversible blindness. Using a previously described protocol, the iPS cells were directed to differentiate toward a retinal fate through a step-wise process that proceeds through all of the major stages of neuroretinal development. The differentiation process was monitored for a period of 70 days for the differentiation of retinal cell types and 150 days for astrocyte development. The different stages of differentiation and the individually derived somatic cell types were characterized by the expression of developmentally associated transcription factors specific to each cell type. Further approaches were undertaken to characterize the morphological differences between RGCs and other neuroretinal cell types derived in the process. The results of this study successfully demonstrated that Usher syndrome patient derived iPS cells differentiated to the affected photoreceptors of Usher syndrome along with other mature retinal cell types, chronologically analogous to the development of the cell types in a mature human retina. This study also established a robust method for the in vitro derivation of RGCs and astrocytes from human iPS cells and provided novel methodologies and evidence to characterize these individual somatic cell types. Overall, this study provides a unique insight into the application of human pluripotent stem cell biology by establishing a novel platform for future studies of in vitro disease modeling of the retinal degenerative diseases: Usher syndrome and glaucoma. In downstream applications of this study, the disease relevant cell types derived from human iPS cells can be used as tools to further study disease progression, drug screening and cell replacement strategies.

Degeneration

Differentiation

Disease Modeling

Glaucoma

Induced Pluripotent Stem Cell

Retina

Usher's syndrome -- Pathophysiology

Glaucoma -- Alternative treatment

Retinitis pigmentosa -- Pathophysiology

Genetic disorders -- Diagnosis

Embryonic stem cells -- Research

Human cell culture -- Research

Cell differentiation -- Analysis

Stem cells -- Transplantation -- Methods

Cellular therapy

Retinal ganglion cells -- Research

Retinal degeneration

Cells -- Morphology

Regenerative medicine -- Research

Transcription factors

Astrocytes -- Morphology

Genetic engineering

Drug testing