Your search keyword '"Ashley McDonough"' showing total 18 results

1. Unipolar (Dendritic) Brush Cells Are Morphologically Complex and Require Tbr2 for Differentiation and Migration

Author

Ashley McDonough, Gina E. Elsen, Ray M. Daza, Amelia R. Bachleda, Donald Pizzo, Olivia M. DelleTorri, and Robert F. Hevner

Subjects

unipolar brush cells, Tbr2, cerebellum, development, cell migration, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Previous studies demonstrated specific expression of transcription factor Tbr2 in unipolar brush cells (UBCs) of the cerebellum during development and adulthood. To further study UBCs and the role of Tbr2 in their development we examined UBC morphology in transgenic mouse lines (reporter and lineage tracer) and also examined the effects of Tbr2 deficiency in Tbr2 (MGI: Eomes) conditional knock-out (cKO) mice. In Tbr2 reporter and lineage tracer cerebellum, UBCs exhibited more complex morphologies than previously reported including multiple dendrites, bifurcating dendrites, and up to four dendritic brushes. We propose that “dendritic brush cells” (DBCs) may be a more apt nomenclature. In Tbr2 cKO cerebellum, mature UBCs were completely absent. Migration of UBC precursors from rhombic lip to cerebellar cortex and other nuclei was impaired in Tbr2 cKO mice. Our results indicate that UBC migration and differentiation are sensitive to Tbr2 deficiency. To investigate whether UBCs develop similarly in humans as in rodents, we studied Tbr2 expression in mid-gestational human cerebellum. Remarkably, Tbr2+ UBC precursors migrate along the same pathways in humans as in rodent cerebellum and disperse to create the same “fountain-like” appearance characteristic of UBCs exiting the rhombic lip.

Published

2021

2. Endogenous Proliferation after Spinal Cord Injury in Animal Models

Author

Ashley McDonough and Verónica Martínez-Cerdeño

Subjects

Internal medicine, RC31-1245

Abstract

Spinal cord injury (SCI) results in motor and sensory deficits, the severity of which depends on the level and extent of the injury. Animal models for SCI research include transection, contusion, and compression mouse models. In this paper we will discuss the endogenous stem cell response to SCI in animal models. All SCI animal models experience a similar peak of cell proliferation three days after injury; however, each specific type of injury promotes a specific and distinct stem cell response. For example, the transection model results in a strong and localized initial increase of proliferation, while in contusion and compression models, the initial level of proliferation is lower but encompasses the entire rostrocaudal extent of the spinal cord. All injury types result in an increased ependymal proliferation, but only in contusion and compression models is there a significant level of proliferation in the lateral regions of the spinal cord. Finally, the fate of newly generated cells varies from a mainly oligodendrocyte fate in contusion and compression to a mostly astrocyte fate in the transection model. Here we will discuss the potential of endogenous stem/progenitor cell manipulation as a therapeutic tool to treat SCI.

Published

2012

3. Operations and Supply Chain Management Essentials You Always Wanted to Know

Author

Vibrant Publishers, Ashley McDonough

Published

2019

4. Abstract WP219: Repurposing The K Ca 3.1 Inhibitor Senicapoc For Treatment Of Acute Ischemic Stroke

Author

Jonathan R Weinstein, Ruth D Lee, Yi-je Jay Chen, Mitzi Adler-Wachter, Brendan Schweitzer, Ashley McDonough, and Heike Wulff

Subjects

Advanced and Specialized Nursing, Neurology (clinical), Cardiology and Cardiovascular Medicine

Abstract

Background: Acute ischemic stroke (AIS) is a leading cause of death and long-term disability. Both microglia (MG) and infiltrating macrophages (MP) are critical effector cell types in ischemic brain injury and recovery. K Ca 3.1 is a calcium-activated potassium channel that is upregulated in reactive MG and MP. Studies using either genetic deletion or pharmacological inhibition of K Ca 3.1 demonstrated that this channel is critical for pro-inflammatory activation of MG/MP as well as exacerbation of stroke pathophysiology. Senicapoc (ICA-17043) is a K Ca 3.1-specific inhibitor that has been used in human clinical trials for non-neurological indications (sickle cell anemia, asthma) and was proven safe. Here we evaluate the potential for repurposing senicapoc for AIS. Methods: Young adult male and female mice underwent 60 min middle cerebral artery occlusion (MCAO)/reperfusion. MCAO was monitored by laser doppler. Senicapoc’s pharmacokinetic (PK) profile was determined using high performance liquid chromatography - mass spectroscopy. Drug levels in plasma and brain were quantified at multiple time points post administration. Effects of senicapoc on post-stroke release of cytokines/chemokines was determined by multiplex ELISA. Inflammatory infiltrates were quantified with flow cytometry. Efficacy studies included: (i) infarct volume (MRI T2), white matter integrity (DTI) and longitudinal neurobehavioral outcomes (NBO). In-vitro chromogenic assay was used to assess senicapoc’s effect on proteolytic activity of tissue plasminogen activator (tPA). Results: Administration of senicapoc (40 mg/kg, i.p.) twice daily for seven days starting 12 h after MCAO resulted in ~55% reduction in infarct volume with corresponding improvements in NBO. Free senicapoc levels in brain ranged from 20 - 200 nM in stroked mice at 1, 4 & 12 hours following administration. All values exceeded senicapoc’s IC 50 (11 nM) for K Ca 3.1. Senicapoc, at up to 5 μM, had no effect on tPA’s proteolytic activity. Conclusions: We provide proof-of-concept data that senicapoc, administered in an extended temporal window, can markedly reduce infarct volume and improve NBO in a mouse model of AIS. Senicapoc demonstrated favorable PK and CNS penetration. It did not interfere with tPA.

Published

2023

5. Abstract WP243: Csf1r Antagonism Abolishes Ischemic Preconditioning Mediated Protection In White Matter

Author

Margaret Hamner, Ashley McDonough, Cara Nielson, Davin Gong, Levi Todd, German Rojas, Thomas Reh, Bruce R Ransom, and Jonathan R Weinstein

Subjects

Advanced and Specialized Nursing, Neurology (clinical), Cardiology and Cardiovascular Medicine

Abstract

Background: Ischemic preconditioning (IPC) is a robust protective phenomenon whereby brief ischemic exposure confers protection against a subsequent prolonged ischemic challenge. IPC has been studied primarily in gray matter predominant models, however, stroke significantly impacts white matter (WM). We have previously reported development of a WM IPC model in the mouse optic nerve (MON), a fully myelinated CNS WM tract. We identified innate immune signaling pathways as required for axonal protection, however the cell type(s) responsible for IPC in WM are unknown. Here we characterize the effects of microglial depletion on IPC-induced protection against OGD-mediated injury to: (i) axonal compound action potential (CAP) recovery, (ii) axonal structural integrity, (iii) oligodendrocyte viability and (iv) nodes of Ranvier (NoR) in MON. Methods: Following microglial depletion by pharmacologic treatment with colony stimulating factor 1 receptor (CSF1R) inhibitor PLX5622, MONs were exposed to transient ischemia in vivo, acutely isolated, and subjected to oxygen-glucose deprivation (OGD) ex vivo to simulate a severe ischemic injury. Functional and structural axonal recovery was assessed by electrophysiology with recording of CAP and immunofluorescent/confocal microscopy followed by quantitative stereology. Results: Microglial depletion eliminated IPC-mediated protection of axonal function but intriguingly had no effect on recovery after acute ischemic injury alone (i.e. in the absence of IPC). Microglial depletion abrogated IPC-mediated protective effects on both axonal integrity and the survival of mature (APC+) oligodendrocytes after exposure to OGD. IPC-mediated protection was determined to be independent of retinal injury. Effects on NoR remain under investigation. Conclusions: Based on these findings, we conclude that preconditioned, but not naïve, microglia are critical in the endogenous IPC-induced protective response against ischemic injury that occurs in WM. Thus, preconditioned microglia are a critical cellular target for future therapeutics designed to enhance WM recovery from acute ischemic injury (stroke). Furthermore, our data suggest that IPC-mediated protection in WM is anatomically intrinsic to WM.

Published

2023

6. A Subpopulation of Microglia Generated in the Adult Mouse Brain Originates from Prominin-1-Expressing Progenitors

Author

Katherine E. Prater, Rachel A. Chernoff, Macarena S. Aloi, Jasmine L. Pathan, Jonathan Weinstein, Gwenn A. Garden, Chloe N. Winston, Matthew P. Sadgrove, Stephanie Davidson, Wei Su, Ashley McDonough, and Dannielle Zierath

Subjects

Male, Myeloid, Population, Biology, Stem cell marker, Mice, Fate mapping, medicine, Animals, AC133 Antigen, Progenitor cell, education, Research Articles, Cell Proliferation, Progenitor, education.field_of_study, Innate immune system, Microglia, General Neuroscience, Brain, Cell Differentiation, Cell biology, medicine.anatomical_structure, nervous system, Female

Abstract

Microglia maintain brain health and play important roles in disease and injury. Despite the known ability of microglia to proliferate, the precise nature of the population or populations capable of generating new microglia in the adult brain remains controversial. We identified Prominin-1 (Prom1; also known as CD133) as a putative cell surface marker of committed brain myeloid progenitor cells. We demonstrate that Prom1-expressing cells isolated from mixed cortical cultures will generate new microglia in vitro. To determine whether Prom1-expressing cells generate new microglia in vivo, we used tamoxifen inducible fate mapping in male and female mice. Induction of Cre recombinase activity at 10 weeks in Prom1-expressing cells leads to the expression of TdTomato in all Prom1-expressing progenitors and newly generated daughter cells. We observed a population of new TdTomato-expressing microglia at 6 months of age that increased in size at 9 months. When microglia proliferation was induced using a transient ischemia/reperfusion paradigm, little proliferation from the Prom1-expressing progenitors was observed with the majority of new microglia derived from Prom1-negative cells. Together, these findings reveal that Prom1-expressing myeloid progenitor cells contribute to the generation of new microglia both in vitro and in vivo. Furthermore, these findings demonstrate the existence of an undifferentiated myeloid progenitor population in the adult mouse brain that expresses Prom1. We conclude that Prom1-expressing myeloid progenitors contribute to new microglia genesis in the uninjured brain but not in response to ischemia/reperfusion. SIGNIFICANCE STATEMENT Microglia, the innate immune cells of the CNS, can divide to slowly generate new microglia throughout life. Newly generated microglia may influence inflammatory responses to injury or neurodegeneration. However, the origins of the new microglia in the brain have been controversial. Our research demonstrates that some newly born microglia in a healthy brain are derived from cells that express the stem cell marker Prominin-1. This is the first time Prominin-1 cells are shown to generate microglia.

Published

2021

7. Microglial depletion abolishes ischemic preconditioning in white matter

Author

Margaret A. Hamner, Ashley McDonough, Davin C. Gong, Levi J. Todd, German Rojas, Sibylle Hodecker, Christopher B. Ransom, Thomas A. Reh, Bruce R. Ransom, and Jonathan R. Weinstein

Subjects

Cerebral Cortex, Stroke, Cellular and Molecular Neuroscience, Mice, Neurology, Animals, Microglia, Ischemic Preconditioning, White Matter, Article

Abstract

Ischemic preconditioning (IPC) is a phenomenon whereby a brief, non-injurious ischemic exposure enhances tolerance to a subsequent ischemic challenge. The mechanism of IPC has mainly been studied in rodent stroke models where gray matter (GM) constitutes about 85% of the cerebrum. In humans, white matter (WM) is 50% of cerebral volume and is a critical component of stroke damage. We developed a novel CNS WM IPC model using the mouse optic nerve (MON) and identified the involved immune signaling pathways. Here we tested the hypothesis that microglia are necessary for WM IPC. Microglia were depleted by treatment with the colony stimulating factor receptor-1 (CSFR1) inhibitor PLX5622. MONs were exposed to transient ischemia in vivo, acutely isolated 72 hours later, and subjected to oxygen-glucose deprivation (OGD) to simulate a severe ischemic injury (i.e. stroke). Functional and structural axonal recovery was assessed by recording compound action potentials (CAPs) and by microscopy using quantitative stereology. Microglial depletion eliminated IPC-mediated protection. In control mice, CAP recovery was improved in preconditioned MONs compared with non-preconditioned MONs, however, in PLX5622-treated mice, we observed no difference in CAP recovery between preconditioned and non-preconditioned MONs. Microglial depletion also abolished IPC protective effects on axonal integrity and survival of mature (APC(+)) oligodendrocytes after OGD. IPC-mediated protection was independent of retinal injury suggesting it results from mechanistic processes intrinsic to ischemia-exposed WM. We conclude that preconditioned microglia are critical for IPC in WM. The ‘preconditioned microglia’ phenotype might protect against other CNS pathologies and is a neurotherapeutic horizon worth exploring.

Published

2021

8. Ischemic preconditioning induces cortical microglial proliferation and a transcriptomic program of robust cell cycle activation

Author

Thomas Möller, James S. Strosnider, Jasmine Shen, Jonathan R. Weinstein, Shahani Noor, Richard V. Lee, Ashley McDonough, Ryan Dodge, Gwenn A. Garden, and Stephanie Davidson

Subjects

Male, 0301 basic medicine, Genetically modified mouse, Ischemia, Biology, Article, Mice, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Downregulation and upregulation, CX3CR1, medicine, Animals, cardiovascular diseases, Ischemic Preconditioning, Cell Proliferation, Cerebral Cortex, Microglia, Cell Cycle, Colocalization, Infarction, Middle Cerebral Artery, medicine.disease, Cell biology, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Neurology, Ischemic preconditioning, Signal transduction, Transcriptome, 030217 neurology & neurosurgery

Abstract

Ischemic preconditioning (IPC) is an experimental phenomenon in which a sub-threshold ischemic insult applied to the brain reduces damage caused by a subsequent more severe ischemic episode. Identifying key molecular and cellular mediators of IPC will provide critical information needed to develop novel therapies for stroke. Here we report that the transcriptomic response of acutely isolated preconditioned cortical microglia is dominated by marked up-regulation of genes involved in cell cycle activation and cellular proliferation. Notably, this transcriptional response occurs in the absence of cortical infarction. We employed ex vivo flow cytometry, immunofluorescent microscopy, and quantitative stereology methods on brain tissue to evaluate microglia proliferation following IPC. Using cellular co-localization of microglial (Iba1) and proliferation (Ki67 and BrdU) markers, we observed a localized increase in the number of microglia and proliferating microglia within the preconditioned hemicortex at 72, but not 24, hours post-IPC. Our quantification demonstrated that the IPC-induced increase in total microglia was due entirely to proliferation. Furthermore, microglia in the preconditioned hemisphere had altered morphology and increased soma volumes, indicative of an activated phenotype. Using transgenic mouse models with either fractalkine receptor (CX3CR1)-haploinsufficiency or systemic type I interferon signaling loss, we determined that microglial proliferation after IPC is dependent on fractalkine signaling but independent of type I interferon signaling. These findings suggest there are multiple distinct targetable signaling pathways in microglia, including CX3CR1-dependent proliferation, that may be involved in IPC-mediated protection.

Published

2019

9. Unipolar (Dendritic) Brush Cells Are Morphologically Complex and Require Tbr2 for Differentiation and Migration

Author

Ray A M Daza, Ashley McDonough, Olivia M DelleTorri, Amelia R Bachleda, Robert F. Hevner, Gina E. Elsen, and Donald P. Pizzo

Subjects

0301 basic medicine, Genetically modified mouse, Cerebellum, Lineage (genetic), cerebellum, cell migration, Biology, lcsh:RC321-571, 03 medical and health sciences, 0302 clinical medicine, medicine, Rhombic lip, Transcription factor, development, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Original Research, General Neuroscience, fungi, Cell migration, unipolar brush cells, Tbr2, Cell biology, Brush Cell, 030104 developmental biology, medicine.anatomical_structure, Cerebellar cortex, 030217 neurology & neurosurgery, Neuroscience

Abstract

Previous studies demonstrated specific expression of transcription factor Tbr2 in unipolar brush cells (UBCs) of the cerebellum during development and adulthood. To further study UBCs and the role of Tbr2 in their development we examined UBC morphology in transgenic mouse lines (reporter and lineage tracer) and also examined the effects of Tbr2 deficiency in Tbr2 (MGI: Eomes) conditional knock-out (cKO) mice. In Tbr2 reporter and lineage tracer cerebellum, UBCs exhibited more complex morphologies than previously reported including multiple dendrites, bifurcating dendrites, and up to four dendritic brushes. We propose that “dendritic brush cells” (DBCs) may be a more apt nomenclature. In Tbr2 cKO cerebellum, mature UBCs were completely absent. Migration of UBC precursors from rhombic lip to cerebellar cortex and other nuclei was impaired in Tbr2 cKO mice. Our results indicate that UBC migration and differentiation are sensitive to Tbr2 deficiency. To investigate whether UBCs develop similarly in humans as in rodents, we studied Tbr2 expression in mid-gestational human cerebellum. Remarkably, Tbr2+ UBC precursors migrate along the same pathways in humans as in rodent cerebellum and disperse to create the same “fountain-like” appearance characteristic of UBCs exiting the rhombic lip.

Published

2021

10. Correction to: Neuroimmune Response in Ischemic Preconditioning

Author

Ashley McDonough and Jonathan R. Weinstein

Subjects

0301 basic medicine, Pharmacology, Toll-like receptor, Innate immune system, Microglia, business.industry, Inflammation, Neuroprotection, Neural stem cell, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Immune system, medicine.anatomical_structure, parasitic diseases, medicine, Ischemic preconditioning, Pharmacology (medical), cardiovascular diseases, Neurology (clinical), medicine.symptom, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Ischemic preconditioning (IPC) is a robust neuroprotective phenomenon in which a brief period of cerebral ischemia confers transient tolerance to subsequent ischemic challenge. Research on IPC has implicated cellular, molecular, and systemic elements of the immune response in this phenomenon. Potent molecular mediators of IPC include innate immune signaling pathways such as Toll-like receptors and type 1 interferons. Brain ischemia results in release of pro- and anti-inflammatory cytokines and chemokines that orchestrate the neuroinflammatory response, resolution of inflammation, and transition to neurological recovery and regeneration. Cellular mediators of IPC include microglia, the resident central nervous system immune cells, astrocytes, and neurons. All of these cell types engage in cross-talk with each other using a multitude of signaling pathways that modulate activation/suppression of each of the other cell types in response to ischemia. As the postischemic neuroimmune response evolves over time there is a shift in function toward provision of trophic support and neuroprotection. Peripheral immune cells infiltrate the central nervous system en masse after stroke and are largely detrimental, with a few subtypes having beneficial, protective effects, though the role of these immune cells in IPC is largely unknown. The role of neural progenitor cells in IPC-mediated neuroprotection is another active area of investigation as is the role of microglial proliferation in this setting. A mechanistic understanding of these molecular and cellular mediators of IPC may not only facilitate more effective direct application of IPC to specific clinical scenarios, but also, more broadly, reveal novel targets for therapeutic intervention in stroke.

Published

2017

11. Microglial Interferon Signaling and White Matter

Author

Richard V. Lee, Ashley McDonough, and Jonathan R. Weinstein

Subjects

0301 basic medicine, Interferon Inducers, Biology, Microgliosis, Biochemistry, Article, Torch syndrome, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Immune system, medicine, Animals, Humans, Neuroinflammation, Innate immune system, Microglia, Multiple sclerosis, Neurodegeneration, General Medicine, medicine.disease, White Matter, Poly I-C, 030104 developmental biology, medicine.anatomical_structure, Interferon Type I, Immunology, Nervous System Diseases, Neuroscience, 030217 neurology & neurosurgery, Signal Transduction

Abstract

Microglia, the resident immune cells of the CNS, are primary regulators of the neuroimmune response to injury. Type I interferons (IFNs), including the IFNαs and IFNβ, are key cytokines in the innate immune system. Their activity is implicated in the regulation of microglial function both during development and in response to neuroinflammation, ischemia, and neurodegeneration. Data from numerous studies in multiple sclerosis (MS) and stroke suggest that type I IFNs can modulate the microglial phenotype, influence the overall neuroimmune milieu, regulate phagocytosis, and affect blood-brain barrier integrity. All of these IFN-induced effects result in numerous downstream consequences on white matter pathology and microglial reactivity. Dysregulation of IFN signaling in mouse models with genetic deficiency in ubiquitin specific protease 18 (USP18) leads to a severe neurological phenotype and neuropathological changes that include white matter microgliosis and pro-inflammatory gene expression in dystrophic microglia. A class of genetic disorders in humans, referred to as pseudo-TORCH syndrome (PTS) for the clinical resemblance to infection-induced TORCH syndrome, also show dysregulation of IFN signaling, which leads to severe neurological developmental disease. In these disorders, the excessive activation of IFN signaling during CNS development results in a destructive interferonopathy with similar induction of microglial dysfunction as seen in USP18 deficient mice. Other recent studies implicate "microgliopathies" more broadly in neurological disorders including Alzheimer's disease (AD) and MS, suggesting that microglia are a potential therapeutic target for disease prevention and/or treatment, with interferon signaling playing a key role in regulating the microglial phenotype.

Published

2017

12. The role of microglia in ischemic preconditioning

Author

Ashley McDonough and Jonathan R. Weinstein

Subjects

0301 basic medicine, Central nervous system, Ischemia, Biology, Article, Brain Ischemia, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Interferon, medicine, Animals, Humans, Ischemic Preconditioning, Innate immune system, Microglia, Toll-Like Receptors, medicine.disease, Stroke, 030104 developmental biology, medicine.anatomical_structure, Neurology, Ischemic preconditioning, Cytokines, Signal transduction, Reprogramming, Neuroscience, 030217 neurology & neurosurgery, medicine.drug

Abstract

Ischemic preconditioning (IPC) is an experimental phenomenon in which a brief ischemic stimulus confers protection against a subsequent prolonged ischemic event. Initially thought to be due to mechanistic changes in neurons, our understanding of IPC has evolved to encompass a global reprogramming of the Central Nervous System (CNS) after transient ischemia/reperfusion that requires innate immune signaling pathways including Toll-like receptors (TLRs) and Type I interferons. Microglia are the CNS resident neuroimmune cells that express these key innate immune receptors. Studies suggest that microglia are required for IPC-mediated neuronal and axonal protection. Multiple paradigms targeting TLRs have converged on a distinctive Type I interferon response in microglia that is critical for preconditioning-mediated protection against ischemia. These pathways can be targeted through administration of TLR agonists, cytokines including interferon-β, and pharmaceutical agents that induce preconditioning through cross-tolerance mechanisms. Transcriptomic analyses and single cell RNA studies point to specific gene expression signatures in microglia that functionally shift these mutable cells to an immunomodulatory or protective phenotype. Although there are technological challenges and gaps in knowledge to overcome, the targeting of specific molecular signaling pathways in microglia is a promising direction for development of novel and effective pharmacotherapies for stroke. Studies on preconditioning in animal models, including nonhuman primates, show promise as prophylactic preconditioning treatments for selected at risk patient populations. In addition, our growing understanding of the mechanisms of IPC-mediated protection is identifying novel cellular and molecular targets for therapeutic interventions that could apply broadly to both acute stroke and chronic vascular cognitive impairment patients.

Published

2019

13. Behavior of Xeno-Transplanted Undifferentiated Human Induced Pluripotent Stem Cells Is Impacted by Microenvironment Without Evidence of Tumors

Author

Paul S. Knoepfler, Craig Steward, Benjamin T. K. Yuen, Catherine T. Le, Jeanelle Ariza, Kayla Horton-Sparks, Ashley McDonough, Priyanka Somanath, Verónica Martínez-Cerdeño, and Bonnie L. Barrilleaux

Subjects

0301 basic medicine, KOSR, Xenotransplantation, medicine.medical_treatment, Population, Induced Pluripotent Stem Cells, Transplantation, Heterologous, Biology, Cell Line, 03 medical and health sciences, Mice, Original Research Reports, medicine, Animals, Humans, Stem Cell Niche, education, Induced pluripotent stem cell, Cells, Cultured, Embryonic Stem Cells, Neurons, education.field_of_study, Brain, Cell Biology, Hematology, Anatomy, Embryonic stem cell, Cell biology, Transplantation, Mice, Inbred C57BL, 030104 developmental biology, Astrocytes, Stem cell, Developmental Biology, Allotransplantation, Stem Cell Transplantation

Abstract

Human pluripotent stem cells (hPSC) have great clinical potential through the use of their differentiated progeny, a population in which there is some concern over risks of tumorigenicity or other unwanted cellular behavior due to residual hPSC. Preclinical studies using human stem cells are most often performed within a xenotransplant context. In this study, we sought to measure how undifferentiated hPSC behave following xenotransplant. We directly transplanted undifferentiated human induced pluripotent stem cells (hIPSC) and human embryonic stem cells (hESC) into the adult mouse brain ventricle and analyzed their fates. No tumors or precancerous lesions were present at more than one year after transplantation. This result differed with the tumorigenic capacity we observed after allotransplantation of mouse ESC into the mouse brain. A substantial population of cellular derivatives of undifferentiated hESC and hIPSC engrafted, survived, and migrated within the mouse brain parenchyma. Within brain structures, transplanted cell distribution followed a very specific pattern, suggesting the existence of distinct microenvironments that offer different degrees of permissibility for engraftment. Most of the transplanted hESC and hIPSC that developed into brain cells were NeuN+ neuronal cells, and no astrocytes were detected. Substantial cell and nuclear fusion occurred between host and transplanted cells, a phenomenon influenced by microenvironment. Overall, hIPSC appear to be largely functionally equivalent to hESC in vivo. Altogether, these data bring new insights into the behavior of stem cells without prior differentiation following xenotransplantation into the adult brain.

Published

2017

14. Ischemia/Reperfusion Induces Interferon-Stimulated Gene Expression in Microglia

Author

Michael Iorga, Thomas Möller, Jessica L.H. Phillips, Jonathan R. Weinstein, Ashley McDonough, Chungeun Lee, Shahani Noor, Richard V. Lee, Thu Le, and Sean C. Murphy

Subjects

0301 basic medicine, Male, Ischemia, Gene Expression, Receptor, Interferon alpha-beta, Biology, Neuroprotection, Brain Ischemia, Brain ischemia, 03 medical and health sciences, Mice, 0302 clinical medicine, medicine, Animals, STAT1, Cells, Cultured, Research Articles, Mice, Knockout, Microglia, Dose-Response Relationship, Drug, General Neuroscience, Interferon-stimulated gene, medicine.disease, Cell biology, Mice, Inbred C57BL, Toll-Like Receptor 4, 030104 developmental biology, medicine.anatomical_structure, Animals, Newborn, Reperfusion Injury, Immunology, STAT protein, biology.protein, Female, Interferons, Reperfusion injury, 030217 neurology & neurosurgery

Abstract

Innate immune signaling is important in the pathophysiology of ischemia/reperfusion (stroke)-induced injury and recovery. Several lines of evidence support a central role for microglia in these processes. Recent work has identified Toll-like receptors (TLRs) and type I interferon (IFN) signaling in both ischemia/reperfusion-induced brain injury and ischemic preconditioning-mediated neuroprotection. To determine the effects of "ischemia/reperfusion-like" conditions on microglia, we performed genomic analyses on wild-type (WT) and TLR4-/- cultured microglia after sequential exposure to hypoxia/hypoglycemia and normoxia/normoglycemia (H/H-N/N). We observed increased expression of type 1 IFN-stimulated genes (ISGs) as the predominant transcriptomal feature of H/H-N/N-exposed WT, but not TLR4-/-, microglia. Microarray analysis on ex vivo sorted microglia from ipsilateral male mouse cortex after a transient in vivo ischemic pulse also demonstrated robust expression of ISGs. Type 1 IFNs, including the IFN-αs and IFN-β, activate the interferon-α/β receptor (IFNAR) complex. We confirmed both in vitro H/H-N/N- and in vivo ischemia/reperfusion-induced microglial ISG responses by quantitative real-time PCR and demonstrated that both were dependent on IFNAR1. We characterized the effects of hypoxia/hypoglycemia on phosphorylation of signal transducer and activator of transcription 1 (STAT1), release of type 1 IFNs, and surface expression of IFNAR1 in microglia. We demonstrated that IFN-β induces dose-dependent secretion of ISG chemokines in cultured microglia and robust ISG expression in microglia both in vitro and in vivo Finally, we demonstrated that the microglial ISG chemokine responses to TLR4 agonists were dependent on TLR4 and IFNAR1. Together, these data suggest novel ischemia/reperfusion-induced pathways for both TLR4-dependent and -independent, IFNAR1-dependent, type 1 IFN signaling in microglia.SIGNIFICANCE STATEMENT Stroke is the fifth leading cause of death in the United States and is a leading cause of serious long-term disability worldwide. Innate immune responses are critical in stroke pathophysiology, and microglia are key cellular effectors in the CNS response to ischemia/reperfusion. Using a transcriptional analysis approach, we identified a robust interferon (IFN)-stimulated gene response within microglia exposed to ischemia/reperfusion in both in vitro and in vivo experimental paradigms. Using a number of complementary techniques, we have demonstrated that these responses are dependent on innate immune signaling components including Toll-like receptor-4 and type I IFNs. We have also elucidated several novel ischemia/reperfusion-induced microglial signaling mechanisms.

Published

2017

15. Compression injury in the mouse spinal cord elicits a specific proliferative response and distinct cell fate acquisition along rostro-caudal and dorso-ventral axes

Author

Angela Monterrubio, Verónica Martínez-Cerdeño, Ashley McDonough, A. N. Hoang, and S. Greenhalgh

Subjects

Pathology, medicine.medical_specialty, Thoracic Vertebrae, OLIG2, Mice, Spinal cord compression, medicine, Animals, Progenitor cell, Spinal cord injury, Spinal Cord Injuries, Cell Proliferation, Microglia, Glial fibrillary acidic protein, biology, General Neuroscience, Cell Differentiation, medicine.disease, Spinal cord, Oligodendrocyte, medicine.anatomical_structure, biology.protein, Female, Inflammation Mediators, Spinal Cord Compression, Neuroscience

Abstract

Harnessing the regenerative capabilities of endogenous precursor cells in the spinal cord may be a useful tool for clinical treatments aimed at replacing cells lost as a consequence of disease or trauma. To better understand the proliferative properties and differentiation potential of the adult spinal cord after injury, we used a mouse model of compression spinal cord injury (SCI). After injury, adult mice were administered BrdU to label mitotic cells and sacrificed at different time-points for immunohistochemical analysis. Our data show that the rate of proliferation increased in all regions of the spinal cord 1day after injury, peaked after 3days, and remained elevated for at least 14days after injury. Proliferation was greater at the injury epicenter than in rostral and caudal adjacent spinal segments. The number of proliferative cells and rate of proliferation varied between dorsal and ventral regions of the spinal cord and between the gray and white matter. Newly generated cells expressed markers for progenitor cells (Nestin and Olig2), oligodendrocytes (Sox10), astrocytes (S100b and glial fibrillary acidic protein), and microglia (Iba1), but not neuronal markers (Map2 and NeuN). Marker expression varied with regard to the dorso-ventral region, rostro-caudal proximity to the injury epicenter, and time after injury. At early time-points after injury, BrdU(+) cells mainly expressed microglial/macrophage and astrocytic markers, while at these same time-points in the control spinal cord the mitotic cells predominately expressed oligodendrocyte and oligodendrocyte progenitor cell markers. The profile of proliferation and cell fate marker expression indicates that after moderate compression, the spinal cord has the capacity to generate a variety of glial cells but not neurons, and that this pattern is space and time specific. Future studies should focus on ways to control proliferation and cell fate after injury to aid the development of cell replacement treatments for SCI.

Published

2013

16. Neuroimmune Response in Ischemic Preconditioning

Author

Ashley McDonough and Jonathan R. Weinstein

Subjects

0301 basic medicine, Inflammation, Review, Neuroprotection, Brain Ischemia, 03 medical and health sciences, 0302 clinical medicine, Immune system, parasitic diseases, Animals, Humans, Medicine, Pharmacology (medical), cardiovascular diseases, Ischemic Preconditioning, Pharmacology, Toll-like receptor, Innate immune system, Microglia, business.industry, Toll-Like Receptors, Correction, Neural stem cell, Stroke, 030104 developmental biology, medicine.anatomical_structure, Cytokines, Encephalitis, Ischemic preconditioning, Neurology (clinical), medicine.symptom, business, Neuroscience, 030217 neurology & neurosurgery

Abstract

Ischemic preconditioning (IPC) is a robust neuroprotective phenomenon in which a brief period of cerebral ischemia confers transient tolerance to subsequent ischemic challenge. Research on IPC has implicated cellular, molecular, and systemic elements of the immune response in this phenomenon. Potent molecular mediators of IPC include innate immune signaling pathways such as Toll-like receptors and type 1 interferons. Brain ischemia results in release of pro- and anti-inflammatory cytokines and chemokines that orchestrate the neuroinflammatory response, resolution of inflammation, and transition to neurological recovery and regeneration. Cellular mediators of IPC include microglia, the resident central nervous system immune cells, astrocytes, and neurons. All of these cell types engage in cross-talk with each other using a multitude of signaling pathways that modulate activation/suppression of each of the other cell types in response to ischemia. As the postischemic neuroimmune response evolves over time there is a shift in function toward provision of trophic support and neuroprotection. Peripheral immune cells infiltrate the central nervous system en masse after stroke and are largely detrimental, with a few subtypes having beneficial, protective effects, though the role of these immune cells in IPC is largely unknown. The role of neural progenitor cells in IPC-mediated neuroprotection is another active area of investigation as is the role of microglial proliferation in this setting. A mechanistic understanding of these molecular and cellular mediators of IPC may not only facilitate more effective direct application of IPC to specific clinical scenarios, but also, more broadly, reveal novel targets for therapeutic intervention in stroke.

Published

2016

17. Calibrated Forceps Model of Spinal Cord Compression Injury

Author

Angela Monterrubio, Jeanelle Ariza, Verónica Martínez-Cerdeño, and Ashley McDonough

Subjects

General Chemical Engineering, medicine.medical_treatment, Hindlimb, Neurodegenerative, Regenerative Medicine, Compression injury, Mice, reproducible animal model, Injury - Trauma - (Head and Spine), Psychology, Spinal Cord Injury, Spinal cord injury, neurological deficit, Issue 98, modified forceps, reproducible deficit, General Neuroscience, Laminectomy, Injuries and accidents, compression model, Surgical Instruments, medicine.anatomical_structure, Spinal Cord, Anesthesia, Neurological, Calibration, Medicine, Cognitive Sciences, murine spinal cord, Forceps, General Biochemistry, Genetics and Molecular Biology, Spinal cord compression, Sensation, medicine, Animals, compression injury, General Immunology and Microbiology, Animal, business.industry, Neurosciences, Reproducibility of Results, medicine.disease, Spinal cord, Disease Models, Animal, SCI, Disease Models, Injury (total) Accidents/Adverse Effects, Biochemistry and Cell Biology, business, Spinal Cord Compression

Abstract

Compression injuries of the murine spinal cord are valuable animal models for the study of spinal cord injury (SCI) and spinal regenerative therapy. The calibrated forceps model of compression injury is a convenient, low cost, and very reproducible animal model for SCI. We used a pair of modified forceps in accordance with the method published by Plemel et al. (2008) to laterally compress the spinal cord to a distance of 0.35 mm. In this video, we will demonstrate a dorsal laminectomy to expose the spinal cord, followed by compression of the spinal cord with the modified forceps. In the video, we will also address issues related to the care of paraplegic laboratory animals. This injury model produces mice that exhibit impairment in sensation, as well as impaired hindlimb locomotor function. Furthermore, this method of injury produces consistent aberrations in the pathology of the SCI, as determined by immunohistochemical methods. After watching this video, viewers should be able to determine the necessary supplies and methods for producing SCI of various severities in the mouse for studies on SCI and/or treatments designed to mitigate impairment after injury.

Published

2015

18. Endogenous proliferation after spinal cord injury in animal models

Author

Verónica Martínez-Cerdeño and Ashley McDonough

Subjects

lcsh:Internal medicine, Pathology, medicine.medical_specialty, Cell growth, business.industry, Endogeny, Cell Biology, Review Article, Spinal cord, medicine.disease, Oligodendrocyte, medicine.anatomical_structure, medicine, Stem cell, Progenitor cell, lcsh:RC31-1245, business, Molecular Biology, Spinal cord injury, Astrocyte

Abstract

Spinal cord injury (SCI) results in motor and sensory deficits, the severity of which depends on the level and extent of the injury. Animal models for SCI research include transection, contusion, and compression mouse models. In this paper we will discuss the endogenous stem cell response to SCI in animal models. All SCI animal models experience a similar peak of cell proliferation three days after injury; however, each specific type of injury promotes a specific and distinct stem cell response. For example, the transection model results in a strong and localized initial increase of proliferation, while in contusion and compression models, the initial level of proliferation is lower but encompasses the entire rostrocaudal extent of the spinal cord. All injury types result in an increased ependymal proliferation, but only in contusion and compression models is there a significant level of proliferation in the lateral regions of the spinal cord. Finally, the fate of newly generated cells varies from a mainly oligodendrocyte fate in contusion and compression to a mostly astrocyte fate in the transection model. Here we will discuss the potential of endogenous stem/progenitor cell manipulation as a therapeutic tool to treat SCI.

Published

2012