Your search keyword '"Kristen L. Wells"' showing total 15 results

1. Modulation of insulin secretion by RBFOX2-mediated alternative splicing

Author

Nicole D. Moss, Kristen L. Wells, Alexandra Theis, Yong-Kyung Kim, Aliya F. Spigelman, Xiong Liu, Patrick E. MacDonald, and Lori Sussel

Subjects

Science

Abstract

Abstract Insulin secretion is a tightly regulated process that is vital for maintaining blood glucose homeostasis. Although the molecular components of insulin granule trafficking and secretion are well established, how they are regulated to rapidly fine-tune secretion in response to changing environmental conditions is not well characterized. Recent studies have determined that dysregulation of RNA-binding proteins (RBPs) and aberrant mRNA splicing occurs at the onset of diabetes. We demonstrate that the RBP, RBFOX2, is a critical regulator of insulin secretion through the alternative splicing of genes required for insulin granule docking and exocytosis. Conditional mutation of Rbfox2 in the mouse pancreas results in decreased insulin secretion and impaired blood glucose homeostasis. Consistent with defects in secretion, we observe reduced insulin granule docking and corresponding splicing defects in the SNARE complex components. These findings identify an additional mechanism for modulating insulin secretion in both healthy and dysfunctional pancreatic β cells.

Published

2023

2. Zinc transporter 8 haploinsufficiency protects against beta cell dysfunction in type 1 diabetes by increasing mitochondrial respiration

Author

Yong Kyung Kim, Jay A. Walters, Nicole D. Moss, Kristen L. Wells, Ryan Sheridan, Jose G. Miranda, Richard K.P. Benninger, Laura L. Pyle, Richard M. O'Brien, Lori Sussel, and Howard W. Davidson

Subjects

Type 1 diabetes, Zinc transporter 8, Mitochondria, NOD mouse, Islets of langerhans, Internal medicine, RC31-1245

Abstract

Objective: Zinc transporter 8 (ZnT8) is a major humoral target in human type 1 diabetes (T1D). Polymorphic variants of Slc30A8, which encodes ZnT8, are also associated with protection from type 2 diabetes (T2D). The current study examined whether ZnT8 might play a role beyond simply being a target of autoimmunity in the pathophysiology of T1D. Methods: The phenotypes of NOD mice with complete or partial global loss of ZnT8 were determined using a combination of disease incidence, histological, transcriptomic, and metabolic analyses. Results: Unexpectedly, while complete loss of ZnT8 accelerated spontaneous T1D, heterozygosity was partially protective. In vivo and in vitro studies of ZnT8 deficient NOD.SCID mice suggested that the accelerated disease was due to more rampant autoimmunity. Conversely, beta cells in heterozygous animals uniquely displayed increased mitochondrial fitness under mild proinflammatory conditions. Conclusions: In pancreatic beta cells and immune cell populations, Zn2+ plays a key role as a regulator of redox signaling and as an independent secondary messenger. Importantly, Zn2+ also plays a major role in maintaining mitochondrial homeostasis. Our results suggest that regulating mitochondrial fitness by altering intra-islet zinc homeostasis may provide a novel mechanism to modulate T1D pathophysiology.

Published

2022

3. Small cell carcinoma of the ovary hypercalcemic type (SCCOHT): A review and novel case with dual germline SMARCA4 and BRCA2 mutations

Author

Brooke E. Sanders, Rebecca Wolsky, Elizabeth S. Doughty, Kristen L. Wells, Debashis Ghosh, Lisa Ku, Joseph G. Pressey, Benjamin G. Bitler, and Lindsay W. Brubaker

Subjects

Small cell carcinoma of the ovary, PARP inhibitor, Transcriptomics, Gynecology and obstetrics, RG1-991, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Small cell carcinoma of the ovary hypercalcemic type (SCCOHT) is a rare and aggressive disease. While classically linked to mutations in SMARCA4, we describe a case in a patient with both SMARCA4 and BRCA2 germline mutations. We describe her disease presentation, histopathology and treatment with adjuvant systemic chemotherapy, interval hyperthermic intraperitoneal chemotherapy, high dose chemotherapy with stem cell rescue, and maintenance with a poly-ADP-ribose polymerase inhibitor (PARPi). Additionally, we share spatial transcriptomics completed on original tumor.

Published

2022

4. Dynamic changes in β-cell [Ca2+] regulate NFAT activation, gene transcription, and islet gap junction communication

Author

Jose G. Miranda, Wolfgang E. Schleicher, Kristen L. Wells, David G. Ramirez, Samantha P. Landgrave, and Richard K.P. Benninger

Subjects

NFAT, Ca2+, Optogenetics, Transcription, Internal medicine, RC31-1245

Abstract

Objective: Diabetes occurs because of insufficient insulin secretion due to β-cell dysfunction within the islet of Langerhans. Elevated glucose levels trigger β-cell membrane depolarization, action potential generation, and slow sustained free-Ca2+ ([Ca2+]) oscillations, which trigger insulin release. Nuclear factor of activated T-cell (NFAT) is a transcription factor, which is regulated by the increases in [Ca2+] and calceineurin (CaN) activation. NFAT regulation links cell activity with gene transcription in many systems and regulates proliferation and insulin granule biogenesis within the β-cell. However, the link between the regulation of β-cell electrical activity and oscillatory [Ca2+] dynamics with NFAT activation and downstream transcription is poorly understood. Here, we tested whether dynamic changes to β-cell electrical activity and [Ca2+] regulate NFAT activation and downstream transcription. Methods: In cell lines, mouse islets, and human islets, including those from donors with type 2 diabetes, we applied both agonists/antagonists of ion channels together with optogenetics to modulate β-cell electrical activity. We measured the dynamics of [Ca2+] and NFAT activation as well as performed whole transcriptome and functional analyses. Results: Both glucose-induced membrane depolarization and optogenetic stimulation triggered NFAT activation as well as increased the transcription of NFAT targets and intermediate early genes (IEGs). Importantly, slow, sustained [Ca2+] oscillation conditions led to NFAT activation and downstream transcription. In contrast, in human islets from donors with type2 diabetes, NFAT activation by glucose was diminished, but rescued upon pharmacological stimulation of electrical activity. NFAT activation regulated GJD2 expression and increased Cx36 gap junction permeability upon elevated oscillatory [Ca2+] dynamics. However, it is unclear if NFAT directly binds the GJD2 gene to regulate expression. Conclusions: This study provides an insight into the specific patterns of electrical activity that regulate NFAT activation, gene transcription, and islet function. In addition, it provides information on how these factors are disrupted in diabetes.

Published

2022

5. Combined transient ablation and single-cell RNA-sequencing reveals the development of medullary thymic epithelial cells

Author

Kristen L Wells, Corey N Miller, Andreas R Gschwind, Wu Wei, Jonah D Phipps, Mark S Anderson, and Lars M Steinmetz

Subjects

single-cell transcriptomics, medullary thymic epithelial cell, immune system, Medicine, Science, Biology (General), QH301-705.5

Abstract

Medullary thymic epithelial cells (mTECs) play a critical role in central immune tolerance by mediating negative selection of autoreactive T cells through the collective expression of the peripheral self-antigen compartment, including tissue-specific antigens (TSAs). Recent work has shown that gene-expression patterns within the mTEC compartment are heterogenous and include multiple differentiated cell states. To further define mTEC development and medullary epithelial lineage relationships, we combined lineage tracing and recovery from transient in vivo mTEC ablation with single-cell RNA-sequencing in Mus musculus. The combination of bioinformatic and experimental approaches revealed a non-stem transit-amplifying population of cycling mTECs that preceded Aire expression. We propose a branching model of mTEC development wherein a heterogeneous pool of transit-amplifying cells gives rise to Aire- and Ccl21a-expressing mTEC subsets. We further use experimental techniques to show that within the Aire-expressing developmental branch, TSA expression peaked as Aire expression decreased, implying Aire expression must be established before TSA expression can occur. Collectively, these data provide a roadmap of mTEC development and demonstrate the power of combinatorial approaches leveraging both in vivo models and high-dimensional datasets.

Published

2020

6. Identification of an anergic BND cell–derived activated B cell population (BND2) in young-onset type 1 diabetes patients

Author

Zachary C. Stensland, Christopher A. Magera, Hali Broncucia, Brittany D. Gomez, Nasha M. Rios-Guzman, Kristen L. Wells, Catherine A. Nicholas, Marynette Rihanek, Maya J. Hunter, Kevin P. Toole, Peter A. Gottlieb, and Mia J. Smith

Subjects

Immunology, Immunology and Allergy

Abstract

Recent evidence suggests a role for B cells in the pathogenesis of young-onset type 1 diabetes (T1D), wherein rapid progression occurs. However, little is known regarding the specificity, phenotype, and function of B cells in young-onset T1D. We performed a cross-sectional analysis comparing insulin-reactive to tetanus-reactive B cells in the blood of T1D and controls using mass cytometry. Unsupervised clustering revealed the existence of a highly activated B cell subset we term BND2 that falls within the previously defined anergic BND subset. We found a specific increase in the frequency of insulin-reactive BND2 cells in the blood of young-onset T1D donors, which was further enriched in the pancreatic lymph nodes of T1D donors. The frequency of insulin-binding BND2 cells correlated with anti-insulin autoantibody levels. We demonstrate BND2 cells are pre-plasma cells and can likely act as APCs to T cells. These findings identify an antigen-specific B cell subset that may play a role in the rapid progression of young-onset T1D.

Published

2023

7. Uterine injury during diestrus leads to embryo spacing defects and perturbations in the COX pathway in subsequent pregnancies

Author

Elisa T. Zhang, Kristen L. Wells, Lars Steinmetz, and Julie C. Baker

Subjects

embryonic structures

Abstract

Uterine injury from procedures such as Cesarean sections (C-sections) often have severe consequences on subsequent pregnancy outcomes, leading to disorders such as placenta previa, placenta accreta, and infertility. With rates of C-section at approximately 30% of deliveries in the US and that are projected to continue to climb, a deeper understanding of the mechanisms by which these pregnancy disorders arise and opportunities for intervention are needed. However, there are no animal models to date that comprehensively assess the consequences of uterine injury. Here we describe a rodent model of uterine injury on subsequent in utero outcomes. We observed three distinct phenotypes: increased rates of resorption and death, embryo spacing defects, and placenta accreta-like features of reduced decidua and expansion of invasive trophoblasts. We show that the appearance of embryo spacing defects depends entirely on the phase of estrous cycle at the time of injury. Using RNA-seq, we identified perturbations in the expression of components of the COX/prostaglandin pathway after recovery from injury, a pathway that has previously been demonstrated to play an important role in embryo spacing. Therefore, we demonstrate that uterine damage in this mouse model causes morphological and molecular changes, most notably perturbed expression of COX/prostaglandin pathway-related genes, that ultimately lead to placental and embryonic developmental defects.

Published

2022

8. Integrated single-cell transcriptomics and epigenomics reveals strong germinal center-associated etiology of autoimmune risk loci

Author

Hamish W King, Robson Capasso, Mark M. Davis, Arwa Kathiria, Lars M. Steinmetz, Zohar Shipony, Kristen L. Wells, Nara Orban, Louisa K. James, William J. Greenleaf, Caleb A. Lareau, and Lisa E. Wagar

Subjects

Epigenomics, Single cell transcriptomics, Immunology, Palatine Tonsil, Autoimmunity, Biology, Article, Humans, Homeodomain Proteins, Sequence Analysis, RNA, Interleukins, food and beverages, Peripheral tolerance, Germinal center, Cell Differentiation, General Medicine, Limiting, Acquired immune system, Germinal Center, Associated etiology, Trans-Activators, Single-Cell Analysis, Transcriptome, Transcription Factors

Abstract

The germinal center (GC) response is critical for both effective adaptive immunity and establishing peripheral tolerance by limiting autoreactive B cells. Dysfunction in these processes can lead to defective immune responses to infection or contribute to autoimmune disease. To understand the gene regulatory principles underlying the GC response, we generated a single-cell transcriptomic and epigenomic atlas of the human tonsil, a widely studied and representative lymphoid tissue. We characterize diverse immune cell subsets and build a trajectory of dynamic gene expression and transcription factor activity during B cell activation, GC formation, and plasma cell differentiation. We subsequently leverage cell type-specific transcriptomic and epigenomic maps to interpret potential regulatory impact of genetic variants implicated in autoimmunity, revealing that many exhibit their greatest regulatory potential in GC-associated cellular populations. These included gene loci linked with known roles in GC biology (IL21, IL21R, IL4R, BCL6) and transcription factors regulating B cell differentiation (POU2AF1, HHEX). Together, these analyses provide a powerful new cell type-resolved resource for the interpretation of cellular and genetic causes underpinning autoimmune disease.

Published

2021

9. Integrated single-cell transcriptomics and epigenomics reveals strong germinal center-associated etiology of autoimmune risk loci

Author

William J. Greenleaf, Robson Capasso, Zohar Shipony, Lars M. Steinmetz, Louisa K. James, Caleb A. Lareau, Hamish W King, Nara Orban, Arwa Kathiria, Kristen L. Wells, Lisa E. Wagar, and Mark M. Davis

Subjects

Autoimmune disease, Immune system, Plasma cell differentiation, medicine, Germinal center, Peripheral tolerance, Computational biology, Biology, medicine.disease, Acquired immune system, Epigenomics, Chromatin

Abstract

The germinal center (GC) response is critical for both effective adaptive immunity and establishing peripheral tolerance by limiting auto-reactive B cells. Dysfunction in these processes can lead to defects in immune response to pathogens or contribute to autoimmune disease. To understand the gene regulatory principles underlying the GC response, we generated a single-cell transcriptomic and epigenomic atlas of the human tonsil, a widely studied and representative lymphoid tissue. We characterize diverse immune cell subsets and build a trajectory of dynamic gene expression and transcription factor activity during B cell activation, GC formation, and plasma cell differentiation. We subsequently leverage cell type-specific transcriptomic and epigenomic maps to interpret potential regulatory impact of genetic variants implicated in autoimmunity, revealing that many exhibit their greatest regulatory potential in GC cell populations. Together, these analyses provide a powerful new cell type-resolved resource for the interpretation of cellular and genetic causes underpinning autoimmune disease.One sentence summarySingle-cell chromatin accessibility landscapes of immune cell subsets reveal regulatory potential of autoimmune-associated genetic variants during the germinal center response.

Published

2021

10. Dynamic changes in β-cell [Ca

Author

Jose G, Miranda, Wolfgang E, Schleicher, Kristen L, Wells, David G, Ramirez, Samantha P, Landgrave, and Richard K P, Benninger

Subjects

Optogenetics, Islets of Langerhans, Mice, Ca2+, NFAT, Diabetes Mellitus, Type 2, Transcription, Genetic, Animals, Gap Junctions, Original Article, Cell Communication, Transcription

Abstract

Objective Diabetes occurs because of insufficient insulin secretion due to β-cell dysfunction within the islet of Langerhans. Elevated glucose levels trigger β-cell membrane depolarization, action potential generation, and slow sustained free-Ca2+ ([Ca2+]) oscillations, which trigger insulin release. Nuclear factor of activated T-cell (NFAT) is a transcription factor, which is regulated by the increases in [Ca2+] and calceineurin (CaN) activation. NFAT regulation links cell activity with gene transcription in many systems and regulates proliferation and insulin granule biogenesis within the β-cell. However, the link between the regulation of β-cell electrical activity and oscillatory [Ca2+] dynamics with NFAT activation and downstream transcription is poorly understood. Here, we tested whether dynamic changes to β-cell electrical activity and [Ca2+] regulate NFAT activation and downstream transcription. Methods In cell lines, mouse islets, and human islets, including those from donors with type 2 diabetes, we applied both agonists/antagonists of ion channels together with optogenetics to modulate β-cell electrical activity. We measured the dynamics of [Ca2+] and NFAT activation as well as performed whole transcriptome and functional analyses. Results Both glucose-induced membrane depolarization and optogenetic stimulation triggered NFAT activation as well as increased the transcription of NFAT targets and intermediate early genes (IEGs). Importantly, slow, sustained [Ca2+] oscillation conditions led to NFAT activation and downstream transcription. In contrast, in human islets from donors with type2 diabetes, NFAT activation by glucose was diminished, but rescued upon pharmacological stimulation of electrical activity. NFAT activation regulated GJD2 expression and increased Cx36 gap junction permeability upon elevated oscillatory [Ca2+] dynamics. However, it is unclear if NFAT directly binds the GJD2 gene to regulate expression. Conclusions This study provides an insight into the specific patterns of electrical activity that regulate NFAT activation, gene transcription, and islet function. In addition, it provides information on how these factors are disrupted in diabetes., Highlights • Beta-cell membrane depolarization and [Ca2+] elevation rapidly activates NFAT and NFAT-regulated gene transcription. • NFAT activation is frequency dependent, with slow sustained [Ca2+] oscillations required for robust activation. • Rapid NFAT activation is diminished in type 2 diabetes but recoverable by pharmacological membrane depolarization. • NFAT activation enhances GJD2 expression and Cx36 gap junction permeability, yet it is unclear if this regulation is direct.

Published

2021

11. Author response: Combined transient ablation and single-cell RNA-sequencing reveals the development of medullary thymic epithelial cells

Author

Wu Wei, Corey N. Miller, Mark S. Anderson, Jonah D Phipps, Kristen L. Wells, Andreas R Gschwind, and Lars M. Steinmetz

Subjects

medicine.anatomical_structure, Medullary cavity, Chemistry, medicine.medical_treatment, Cell, medicine, RNA, Transient (oscillation), Ablation, Cell biology

Published

2020

12. Combined transient ablation and single cell RNA sequencing reveals the development of medullary thymic epithelial cells

Author

Lars M. Steinmetz, Wu Wei, Mark S. Anderson, Andreas R Gschwind, Kristen L. Wells, Corey N. Miller, and Jonah D Phipps

Subjects

education.field_of_study, Cellular differentiation, Cell, Population, RNA, Biology, Cell biology, Immune tolerance, Negative selection, medicine.anatomical_structure, Antigen, Gene expression, medicine, education

Abstract

Medullary thymic epithelial cells (mTECs) play a critical role in central immune tolerance by mediating negative selection of autoreactive T cells through the collective expression of the peripheral self-antigen compartment, including tissue-specific antigens (TSAs). Recent work has shown that gene expression patterns within the mTEC compartment are remarkably heterogenous and include multiple differentiated cell states. To further define mTEC development and medullary epithelial lineage relationships, we combined lineage tracing and recovery from transient in vivo mTEC ablation with single cell RNA-sequencing. The combination of bioinformatic and experimental approaches revealed a non-stem transit-amplifying population of cycling mTECs that preceded Aire expression. Based on our findings, we propose a branching model of mTEC development wherein a heterogeneous pool of transit-amplifying cells gives rise to Aire- and Ccl21a-expressing mTEC subsets. We further use experimental techniques to show that within the Aire-expressing developmental branch, TSA expression peaked as Aire expression decreased, implying Aire expression must be established before TSA expression can occur. Collectively, these data provide a higher order roadmap of mTEC development and demonstrate the power of combinatorial approaches leveraging both in vivo models and high-dimensional datasets.

Published

2020

13. Combined transient ablation and single-cell RNA-sequencing reveals the development of medullary thymic epithelial cells

Author

Wu Wei, Kristen L. Wells, Jonah D Phipps, Andreas R Gschwind, Corey N. Miller, Lars M. Steinmetz, and Mark S. Anderson

Subjects

0301 basic medicine, Mouse, Cellular differentiation, Cell, Inbred C57BL, Immune tolerance, immunology, Negative selection, Mice, 0302 clinical medicine, Immunology and Inflammation, genetics, Biology (General), education.field_of_study, General Neuroscience, medullary thymic epithelial cell, Cell Differentiation, General Medicine, Cell biology, Mutant Strains, medicine.anatomical_structure, Medicine, Stem Cell Research - Nonembryonic - Non-Human, Single-Cell Analysis, Sequence Analysis, Research Article, QH301-705.5, Science, 1.1 Normal biological development and functioning, Population, Thymus Gland, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Immune system, Antigen, Underpinning research, medicine, genomics, Animals, Cell Lineage, education, mouse, General Immunology and Microbiology, Sequence Analysis, RNA, RNA, Epithelial Cells, Genetics and Genomics, Stem Cell Research, Mice, Mutant Strains, Mice, Inbred C57BL, immune system, 030104 developmental biology, inflammation, Biochemistry and Cell Biology, single-cell transcriptomics, 030217 neurology & neurosurgery

Abstract

Medullary thymic epithelial cells (mTECs) play a critical role in central immune tolerance by mediating negative selection of autoreactive T cells through the collective expression of the peripheral self-antigen compartment, including tissue-specific antigens (TSAs). Recent work has shown that gene-expression patterns within the mTEC compartment are heterogenous and include multiple differentiated cell states. To further define mTEC development and medullary epithelial lineage relationships, we combined lineage tracing and recovery from transient in vivo mTEC ablation with single-cell RNA-sequencing in Mus musculus. The combination of bioinformatic and experimental approaches revealed a non-stem transit-amplifying population of cycling mTECs that preceded Aire expression. We propose a branching model of mTEC development wherein a heterogeneous pool of transit-amplifying cells gives rise to Aire- and Ccl21a-expressing mTEC subsets. We further use experimental techniques to show that within the Aire-expressing developmental branch, TSA expression peaked as Aire expression decreased, implying Aire expression must be established before TSA expression can occur. Collectively, these data provide a roadmap of mTEC development and demonstrate the power of combinatorial approaches leveraging both in vivo models and high-dimensional datasets., eLife digest Specialized cells in the immune system known as T cells protect the body from infection by destroying disease-causing microbes, such as bacteria or viruses. T cells use proteins on their surface called receptors to stick to infectious microbes and remove them from the body. Some newly developed T-cells, however, contain receptors that recognize and bind to cells that belong in the body. If these faulty T cells are released, they can attack healthy tissues and cause an autoimmune disease. After a new T cell is developed, it gets carried to a gland in the chest known as the thymus. Cells in the thymus called mTECs screen T cells for receptors that may bind to the body’s tissues. mTECs do this by presenting T cells with proteins that are commonly found on the surface of healthy cells in the body. If a T cell recognizes any of these ‘tissue specific proteins’, it is destroyed or given a new role in the body. Some faulty T cells, however, still manage to evade detection. One way to uncover why this might happen is to investigate how mTECs develop. Previous work showed that mTECs transition through various stages before reaching their final form. However, the order in which these events occur remained unclear. To gain a better understanding of these developmental steps, Wells, Miller et al. extracted mTECs from the thymus of mice and analyzed the genetic make-up of individual cells. This uncovered a missing link in mTEC development: a new type of cell that is the immediate predecessor of the final mTEC. These ‘predecessor’ cells were actively growing, highlighting that mTECs can be constantly generated in the body. By probing the genes that generate tissue-specific proteins in mTECs, Wells, Miller et al. revealed that these proteins were only produced for short periods and in the late stages of mTEC development. These findings contribute to our understanding of how mTECs develop to screen T cells. Mapping these developmental stages will make it easier to identify when faulty T cells are able to evade mTECs. This will lead to earlier detection of autoimmune diseases which could result in better treatments.

Published

2020

14. Thymic tuft cells promote an IL4-enriched medulla and shape thymocyte development

Author

Mark S. Anderson, Richard M. Locksley, Lars M. Steinmetz, Corey N. Miller, Joshua L. Pollack, Wint Lwin, Imran S. Khan, Todd C. Metzger, Bruno Kyewski, Aparna R. Rajpurkar, David J. Erle, Kristin Rattay, Irina Proekt, Adam Fries, Haiguang Wang, Kristen L. Wells, Jakob von Moltke, Kristin A. Hogquist, Audrey Parent, and Eric J. Wigton

Subjects

0301 basic medicine, Multidisciplinary, Taste Transduction Pathway, medicine.medical_treatment, Lymphocyte differentiation, Epithelial Cells, Biology, Natural killer T cell, Article, Cell biology, Immune tolerance, 03 medical and health sciences, Thymocyte, 030104 developmental biology, 0302 clinical medicine, Cytokine, medicine, TRPM5, Interleukin 4, 030215 immunology

Abstract

The thymus is responsible for generating a diverse yet self-tolerant pool of T cells1. Although the thymic medulla consists mostly of developing and mature AIRE+ epithelial cells, recent evidence has suggested that there is far greater heterogeneity among medullary thymic epithelial cells than was previously thought2. Here we describe in detail an epithelial subset that is remarkably similar to peripheral tuft cells that are found at mucosal barriers3. Similar to the periphery, thymic tuft cells express the canonical taste transduction pathway and IL-25. However, they are unique in their spatial association with cornified aggregates, ability to present antigens and expression of a broad diversity of taste receptors. Some thymic tuft cells pass through an Aire-expressing stage and depend on a known AIRE-binding partner, HIPK2, for their development. Notably, the taste chemosensory protein TRPM5 is required for their thymic function through which they support the development and polarization of thymic invariant natural killer T cells and act to establish a medullary microenvironment that is enriched in the type 2 cytokine, IL-4. These findings indicate that there is a compartmentalized medullary environment in which differentiation of a minor and highly specialized epithelial subset has a non-redundant role in shaping thymic function.

Published

2018

15. Conserved RNA-Binding Proteins Required for Dendrite Morphogenesis inCaenorhabditis elegansSensory Neurons

Author

Simona Antonacci, Margaret Wolf, Genevieve Kerr, Julia Barney, Courtney Tyus, Eugenia C. Olesnicky, Daniel Forand, Margo A. Simon, Nathan T. Mortimer, Leah Kellogg, Kristen L. Wells, Serena Younes, and Darrell J. Killian

Subjects

Sensory Receptor Cells, Morphogenesis, posttranscriptional regulation, RNA-binding protein, Investigations, PVD neurons, dendrite morphogenesis, RNA interference, Genetics, medicine, Animals, RNA, Messenger, Caenorhabditis elegans, Caenorhabditis elegans Proteins, Molecular Biology, Genetics (clinical), RNA, Double-Stranded, Cell Nucleus, Regulation of gene expression, biology, RNA-Binding Proteins, Dendrites, biology.organism_classification, Sensory neuron, Dendrite morphogenesis, Cell biology, medicine.anatomical_structure, RNA Interference, Drosophila melanogaster

Abstract

The regulation of dendritic branching is critical for sensory reception, cell−cell communication within the nervous system, learning, memory, and behavior. Defects in dendrite morphology are associated with several neurologic disorders; thus, an understanding of the molecular mechanisms that govern dendrite morphogenesis is important. Recent investigations of dendrite morphogenesis have highlighted the importance of gene regulation at the posttranscriptional level. Because RNA-binding proteins mediate many posttranscriptional mechanisms, we decided to investigate the extent to which conserved RNA-binding proteins contribute to dendrite morphogenesis across phyla. Here we identify a core set of RNA-binding proteins that are important for dendrite morphogenesis in the PVD multidendritic sensory neuron in Caenorhabditis elegans. Homologs of each of these genes were previously identified as important in the Drosophila melanogaster dendritic arborization sensory neurons. Our results suggest that RNA processing, mRNA localization, mRNA stability, and translational control are all important mechanisms that contribute to dendrite morphogenesis, and we present a conserved set of RNA-binding proteins that regulate these processes in diverse animal species. Furthermore, homologs of these genes are expressed in the human brain, suggesting that these RNA-binding proteins are candidate regulators of dendrite development in humans.

Published

2015