Your search keyword '"Dario X. Figueroa Velez"' showing total 17 results

1. Infection with Toxoplasma gondii triggers coagulation at the blood-brain barrier and a reduction in cerebral blood flow

Author

Evelyn M. Hoover, Christine A. Schneider, Christian Crouzet, Tatiane S. Lima, Dario X. Figueroa Velez, Cuong J. Tran, Dritan Agalliu, Sunil P. Gandhi, Bernard Choi, and Melissa B. Lodoen

Subjects

Toxoplasma gondii, CNS infection, Thrombosis, Cerebral blood flow, Blood-brain barrier, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Background Immunothrombosis is the process by which the coagulation cascade interacts with the innate immune system to control infection. However, the formation of clots within the brain vasculature can be detrimental to the host. Recent work has demonstrated that Toxoplasma gondii infects and lyses central nervous system (CNS) endothelial cells that form the blood-brain barrier (BBB). However, little is known about the effect of T. gondii infection on the BBB and the functional consequences of infection on cerebral blood flow (CBF) during the different stages of infection. Main body We demonstrate that brain endothelial cells upregulate the adhesion molecules ICAM-1 and VCAM-1 and become morphologically more tortuous during acute T. gondii infection of mice. Longitudinal two-photon imaging of cerebral blood vessels during infection in mice revealed vascular occlusion in the brain, prompting an analysis of the coagulation cascade. We detected platelet-fibrin clots within the cerebral vasculature during acute infection. Analysis of CBF using longitudinal laser-speckle imaging during T. gondii infection demonstrated that CBF decreased during acute infection, recovered during stable chronic infection, and decreased again during reactivation of the infection induced by IFN-γ depletion. Finally, we demonstrate that treatment of mice with a low-molecular-weight heparin, an anticoagulant, during infection partially rescued CBF in T. gondii-infected mice without affecting parasite burden. Conclusions Our data provide insight into the host-pathogen interactions of a CNS parasite within the brain vasculature and suggest that thrombosis and changes in cerebral hemodynamics may be an unappreciated aspect of infection with T. gondii.

Published

2025

2. Publisher Correction: Juvenile depletion of microglia reduces orientation but not high spatial frequency selectivity in mouse V1

Author

Dario X. Figueroa Velez, Miguel Arreola, Carey Y. L. Huh, Kim Green, and Sunil P. Gandhi

Subjects

Medicine, Science

Published

2023

3. Juvenile depletion of microglia reduces orientation but not high spatial frequency selectivity in mouse V1

Author

Dario X. Figueroa Velez, Miguel Arreola, Carey Y. L. Huh, Kim Green, and Sunil P. Gandhi

Subjects

Medicine, Science

Abstract

Abstract Microglia contain multiple mechanisms that shape the synaptic landscape during postnatal development. Whether the synaptic changes mediated by microglia reflect the developmental refinement of neuronal responses in sensory cortices, however, remains poorly understood. In postnatal life, the development of increased orientation and spatial frequency selectivity of neuronal responses in primary visual cortex (V1) supports the emergence of high visual acuity. Here, we used the colony-stimulating factor 1 receptor (CSF1R) inhibitor PLX5622 to rapidly and durably deplete microglia in mice during the juvenile period in which increased orientation and spatial frequency selectivity emerge. Excitatory and inhibitory tuning properties were measured simultaneously using multi-photon calcium imaging in layer II/III of mouse V1. We found that microglia depletion generally increased evoked activity which, in turn, reduced orientation selectivity. Surprisingly, microglia were not required for the emergence of high spatial frequency tuned responses. In addition, microglia depletion did not perturb cortical binocularity, suggesting normal depth processing. Together, our finding that orientation and high spatial frequency selectivity in V1 are differentially supported by microglia reveal that microglia are required normal sensory processing, albeit selectively.

Published

2022

4. Toxoplasma gondii Dissemination in the Brain Is Facilitated by Infiltrating Peripheral Immune Cells

Author

Christine A. Schneider, Dario X. Figueroa Velez, Stephanie B. Orchanian, Lindsey A. Shallberg, Dritan Agalliu, Christopher A. Hunter, Sunil P. Gandhi, and Melissa B. Lodoen

Subjects

Toxoplasma, central nervous system infections, host-pathogen interactions, immunity, parasite, pathogenesis, Microbiology, QR1-502

Abstract

ABSTRACT Despite recent advances in our understanding of pathogenic access to the central nervous system (CNS), the mechanisms by which intracellular pathogens disseminate within the dense cellular network of neural tissue remain poorly understood. To address this issue, longitudinal analysis of Toxoplasma gondii dissemination in the brain was conducted using 2-photon imaging through a cranial window in living mice that transgenically express enhanced green fluorescent protein (eGFP)-claudin-5. Extracellular T. gondii parasites were observed migrating slowly (1.37 ± 1.28 μm/min) and with low displacement within the brain. In contrast, a population of highly motile infected cells transported vacuoles of T. gondii significantly faster (6.30 ± 3.09 μm/min) and with a higher displacement than free parasites. Detailed analysis of microglial dynamics using CX3CR1-GFP mice revealed that T. gondii-infected microglia remained stationary, and infection did not increase the extension/retraction of microglial processes. The role of infiltrating immune cells in shuttling T. gondii was examined by labeling of peripheral hematopoietic cells with anti-CD45 antibody. Infected CD45+ cells were found crawling along the CNS vessel walls and trafficked T. gondii within the brain parenchyma at significantly higher speeds (3.35 ± 1.70 μm/min) than extracellular tachyzoites. Collectively, these findings highlight a dual role for immune cells in neuroprotection and in facilitating parasite dissemination within the brain. IMPORTANCE T. gondii is a foodborne parasite that infects the brain and can cause fatal encephalitis in immunocompromised individuals. However, there is a limited understanding of how the parasites disseminate through the brain and evade immune clearance. We utilized intravital imaging to visualize extracellular T. gondii tachyzoites and infected cells migrating within the infected mouse brain during acute infection. The infection of motile immune cells infiltrating the brain from the periphery significantly increased the dissemination of T. gondii in the brain compared to that of free parasites migrating using their own motility: the speed and displacement of these infected cells would enable them to cover nearly 1 cm of distance per day! Among the infiltrating cells, T. gondii predominantly infected monocytes and CD8+ T cells, indicating that the parasite can hijack immune cells that are critical for controlling the infection in order to enhance their dissemination within the brain.

Published

2022

5. Host interneurons mediate plasticity reactivated by embryonic inhibitory cell transplantation in mouse visual cortex

Author

XiaoTing Zheng, Kirstie J. Salinas, Dario X. Figueroa Velez, Taylor Nakayama, Xiaoxiao Lin, Dhruba Banerjee, Xiangmin Xu, and Sunil P. Gandhi

Subjects

Science

Abstract

Transplantation of embryonic interneurons can restore juvenile plasticity to the adult host visual cortex. Here, the authors show that transplanted embryonic interneurons reactivate cortical plasticity via Neuregulin/ErbB4 signaling in host parvalbumin interneurons.

Published

2021

6. Precocious deposition of perineuronal nets on Parvalbumin inhibitory neurons transplanted into adult visual cortex

Author

Karen P. Bradshaw, Dario X. Figueroa Velez, Mariyam Habeeb, and Sunil P. Gandhi

Subjects

Medicine, Science

Abstract

Abstract The end of the critical period for primary visual cortex (V1) coincides with the deposition of perineuronal nets (PNN) onto Parvalbumin (PV) inhibitory neurons. Recently, we found that transplantation of embryonic inhibitory neurons into adult V1 reinstates a new critical period. Here we used Wisteria Floribunda Agglutinin (WFA) staining to compare the deposition of PNNs onto neurons during normal development and following transplantation at equivalent cell ages. In accord with previous findings, PV and PNN expression increases from negligible levels at postnatal day 14 (P14) to mature levels by P70. In contrast to P14, PNNs are found on transplanted PV neurons by 21 days after transplantation and persist to 105 days after transplantation. This precocious deposition was specific to PV neurons and excluded transplanted neurons expressing Somatostatin. Notably, the onset of PV expression in transplanted inhibitory neurons follows the timing of PV expression in juvenile V1. Moreover, transplantation has no discernible effect on host PNNs. The precocious deposition of PNNs onto transplanted PV neurons suggests that PNN expression identified by WFA does not reflect neuronal maturity and may be an inaccurate marker for transplant-induced plasticity of cortical circuits.

Published

2018

7. Subventricular zone/white matter microglia reconstitute the empty adult microglial niche in a dynamic wave

Author

Lindsay A. Hohsfield, Ali Mortazavi, Sarah E Royer, Dario X. Figueroa Velez, Shan Jiang, Allison R. Najafi, Yasamine Ghorbanian, Matthew A. Inlay, Aileen J. Anderson, Neelakshi Soni, Sung Jin Kim, Joshua D. Crapser, Sunil P. Gandhi, Caden M Henningfield, and Kim N. Green

Subjects

Male, Myeloid, repopulation, Mouse, Cell, microglia, Inbred C57BL, immunology, neuroscience, Mice, Immunology and Inflammation, Lateral Ventricles, Receptors, Homeostasis, 2.1 Biological and endogenous factors, Myeloid Cells, Biology (General), Aetiology, Receptor, Microglia, depletion, General Neuroscience, Brain, General Medicine, Phenotype, White Matter, Cell biology, medicine.anatomical_structure, Receptors, Granulocyte-Macrophage Colony-Stimulating Factor, Neurological, Medicine, medicine.symptom, white matter, Research Article, QH301-705.5, Science, Subventricular zone, Inflammation, Biology, General Biochemistry, Genetics and Molecular Biology, White matter, medicine, Animals, mouse, General Immunology and Microbiology, Animal, Neurosciences, Granulocyte-Macrophage Colony-Stimulating Factor, CSF1R, Mice, Inbred C57BL, Disease Models, Animal, Disease Models, Biochemistry and Cell Biology, Neuroscience

Abstract

Microglia, the brain’s resident myeloid cells, play central roles in brain defense, homeostasis, and disease. Using a prolonged colony-stimulating factor 1 receptor inhibitor (CSF1Ri) approach, we report an unprecedented level of microglial depletion and establish a model system that achieves an empty microglial niche in the adult brain. We identify a myeloid cell that migrates from the subventricular zone and associated white matter areas. Following CSF1Ri, these amoeboid cells migrate radially and tangentially in a dynamic wave filling the brain in a distinct pattern, to replace the microglial-depleted brain. These repopulating cells are enriched in disease-associated microglia genes and exhibit similar phenotypic and transcriptional profiles to white-matter-associated microglia. Our findings shed light on the overlapping and distinct functional complexity and diversity of myeloid cells of the CNS and provide new insight into repopulating microglia function and dynamics in the mouse brain.

Published

2021

8. Author response: Subventricular zone/white matter microglia reconstitute the empty adult microglial niche in a dynamic wave

Author

Sunil P. Gandhi, Sung Jin Kim, Joshua D. Crapser, Shan Jiang, Caden M Henningfield, Ali Mortazavi, Neelakshi Soni, Allison R. Najafi, Dario X. Figueroa Velez, Lindsay A. Hohsfield, Yasamine Ghorbanian, Sarah E Royer, Kim N. Green, Aileen J. Anderson, and Matthew A. Inlay

Subjects

White matter, medicine.anatomical_structure, Microglia, Niche, medicine, Subventricular zone, Biology, Neuroscience

Published

2021

9. Transcranial chronic optical access to longitudinally measure cerebral blood flow

Author

Melissa B. Lodoen, Bernard Choi, Christian Crouzet, Julianna M. Bordas, Sunil P. Gandhi, Dario X. Figueroa Velez, and Evelyn M. Hoover

Subjects

0301 basic medicine, medicine.medical_specialty, Cerebral pathology, Mouse Skull, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Internal medicine, Medicine, Animals, Psychology, Neurology & Neurosurgery, business.industry, General Neuroscience, Skull, Optical Imaging, Hemodynamics, Laser speckle imaging, Neurosciences, Brain, Laser Speckle Imaging, Blood flow, Cerebral blood flow, Brain Disorders, Stroke, Circulation, 030104 developmental biology, medicine.anatomical_structure, Cerebrovascular Circulation, Invasive surgery, In vivo imaging, Cardiology, Vasculature, Surgery, Cognitive Sciences, business, 030217 neurology & neurosurgery, Preclinical imaging

Abstract

Background The regulation of cerebral blood flow is critical for normal brain functioning, and many physiological and pathological conditions can have long-term impacts on cerebral blood flow. However, minimally invasive tools to study chronic changes in animal models are limited. New method We developed a minimally invasive surgical technique (cyanoacrylate skull, CAS) allowing us to image cerebral blood flow longitudinally through the intact mouse skull using laser speckle imaging. Results With CAS we were able to detect acute changes in cerebral blood flow induced by hypercapnic challenge. We were also able to image cerebral blood flow dynamics with laser speckle imaging for over 100 days. Furthermore, the relative cerebral blood flow remained stable in mice from 30 days to greater than 100 days after the surgery. Comparison with existing methods Previously, achieving continuous long-term optical access to measure cerebral blood flow in individual vessels in a mouse model involved invasive surgery. In contrast, the CAS technique presented here is relatively non-invasive, as it allows stable optical access through an intact mouse skull. Conclusions The CAS technique allows researcher to chronically measure cerebral blood flow dynamics for a significant portion of a mouse’s lifespan. This approach may be useful for studying changes in blood flow due to cerebral pathology or for examining the therapeutic effects of modifying cerebral blood flow in mouse models relevant to human disease.

Published

2021

10. Host interneurons mediate plasticity reactivated by embryonic inhibitory cell transplantation in mouse visual cortex

Author

Xiaoxiao Lin, Dario X. Figueroa Velez, Dhruba Banerjee, Sunil P. Gandhi, Taylor Nakayama, Xiangmin Xu, Xiaoting Zheng, and Kirstie J. Salinas

Subjects

0301 basic medicine, Male, Receptor, ErbB-4, genetic structures, Cell Transplantation, Cellular differentiation, General Physics and Astronomy, 0302 clinical medicine, Visual Cortex, Inhibition, Multidisciplinary, Neuronal Plasticity, biology, musculoskeletal, neural, and ocular physiology, Cell Differentiation, Dominance, Ocular, medicine.anatomical_structure, Parvalbumins, Neuronal physiology, Female, Signal Transduction, Interneuron, Science, Neuregulin-1, Sensory system, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Interneurons, Neuroplasticity, medicine, Animals, Sensory deprivation, Regeneration and repair in the nervous system, fungi, General Chemistry, Transplantation, Mice, Inbred C57BL, 030104 developmental biology, Visual cortex, nervous system, Synapses, biology.protein, Neuronal development, Sensory Deprivation, Visual system, Neuroscience, 030217 neurology & neurosurgery, Parvalbumin

Abstract

The adult brain lacks sensitivity to changes in the sensory environment found in the juvenile brain. The transplantation of embryonic interneurons has been shown to restore juvenile plasticity to the adult host visual cortex. It is unclear whether transplanted interneurons directly mediate the renewed cortical plasticity or whether these cells act indirectly by modifying the host interneuron circuitry. Here we find that the transplant-induced reorganization of mouse host circuits is specifically mediated by Neuregulin (NRG1)/ErbB4 signaling in host parvalbumin (PV) interneurons. Brief visual deprivation reduces the visual activity of host PV interneurons but has negligible effects on the responses of transplanted PV interneurons. Exogenous NRG1 both prevents the deprivation-induced reduction in the visual responses of host PV interneurons and blocks the transplant-induced reorganization of the host circuit. While deletion of ErbB4 receptors from host PV interneurons blocks cortical plasticity in the transplant recipients, deletion of the receptors from the donor PV interneurons does not. Altogether, our results indicate that transplanted embryonic interneurons reactivate cortical plasticity by rejuvenating the function of host PV interneurons., Transplantation of embryonic interneurons can restore juvenile plasticity to the adult host visual cortex. Here, the authors show that transplanted embryonic interneurons reactivate cortical plasticity via Neuregulin/ErbB4 signaling in host parvalbumin interneurons.

Published

2020

11. Contralateral Bias of High Spatial Frequency Tuning and Cardinal Direction Selectivity in Mouse Visual Cortex

Author

Kirstie J. Salinas, Hyungtae Kim, Jack Zeitoun, Dario X. Figueroa Velez, and Sunil P. Gandhi

Subjects

Male, 0301 basic medicine, Visual perception, visual acuity, genetic structures, two-photon calcium imaging, spatial frequency selectivity, Visual system, Inbred C57BL, orientation selectivity, Eye, Medical and Health Sciences, Transgenic, Visual processing, Mice, 0302 clinical medicine, Contrast (vision), primary visual cortex, Research Articles, Visual Cortex, media_common, General Neuroscience, medicine.anatomical_structure, binocularity, Neurological, Female, Spatial frequency, Psychology, 1.1 Normal biological development and functioning, media_common.quotation_subject, Mice, Transgenic, 03 medical and health sciences, Underpinning research, Orientation, medicine, Animals, Visual Pathways, Eye Disease and Disorders of Vision, Binocular neurons, Communication, Neurology & Neurosurgery, business.industry, Psychology and Cognitive Sciences, Neurosciences, eye diseases, Mice, Inbred C57BL, 030104 developmental biology, Visual cortex, Space Perception, business, Binocular vision, Neuroscience, Photic Stimulation, 030217 neurology & neurosurgery

Abstract

Binocular mechanisms for visual processing are thought to enhance spatial acuity by combining matched input from the two eyes. Studies in the primary visual cortex of carnivores and primates have confirmed that eye-specific neuronal response properties are largely matched. In recent years, the mouse has emerged as a prominent model for binocular visual processing, yet little is known about the spatial frequency tuning of binocular responses in mouse visual cortex. Using calcium imaging in awake mice of both sexes, we show that the spatial frequency preference of cortical responses to the contralateral eye is ∼35% higher than responses to the ipsilateral eye. Furthermore, we find that neurons in binocular visual cortex that respond only to the contralateral eye are tuned to higher spatial frequencies. Binocular neurons that are well matched in spatial frequency preference are also matched in orientation preference. In contrast, we observe that binocularly mismatched cells are more mismatched in orientation tuning. Furthermore, we find that contralateral responses are more direction-selective than ipsilateral responses and are strongly biased to the cardinal directions. The contralateral bias of high spatial frequency tuning was found in both awake and anesthetized recordings. The distinct properties of contralateral cortical responses may reflect the functional segregation of direction-selective, high spatial frequency-preferring neurons in earlier stages of the central visual pathway. Moreover, these results suggest that the development of binocularity and visual acuity may engage distinct circuits in the mouse visual system.SIGNIFICANCE STATEMENTSeeing through two eyes is thought to improve visual acuity by enhancing sensitivity to fine edges. Using calcium imaging of cellular responses in awake mice, we find surprising asymmetries in the spatial processing of eye-specific visual input in binocular primary visual cortex. The contralateral visual pathway is tuned to higher spatial frequencies than the ipsilateral pathway. At the highest spatial frequencies, the contralateral pathway strongly prefers to respond to visual stimuli along the cardinal (horizontal and vertical) axes. These results suggest that monocular, and not binocular, mechanisms set the limit of spatial acuity in mice. Furthermore, they suggest that the development of visual acuity and binocularity in mice involves different circuits.

Published

2017

12. Long-term Monocular Deprivation during Juvenile Critical Period Disrupts Binocular Integration in Mouse Visual Thalamus

Author

John P. Peach, Jack Zeitoun, Sunil P. Gandhi, Kirstie J. Salinas, Karim Abdelaal, Carey Y. L. Huh, Dario X. Figueroa Velez, Diyue Gu, and Charless C. Fowlkes

Subjects

0301 basic medicine, Male, Visual acuity, genetic structures, Vision, Visual Acuity, Inbred C57BL, Eye, Medical and Health Sciences, Mice, 0302 clinical medicine, Thalamus, Contrast (vision), 2.1 Biological and endogenous factors, visual cortex, Aetiology, Research Articles, Visual Cortex, media_common, Vision, Binocular, education.field_of_study, Brain Mapping, General Neuroscience, Geniculate Bodies, critical period, Monocular deprivation, medicine.anatomical_structure, Neurological, Female, medicine.symptom, media_common.quotation_subject, Population, Biology, Amblyopia, Ocular dominance, 03 medical and health sciences, Vision, Monocular, Ocular, medicine, Animals, dorsolateral geniculate nucleus, education, Eye Disease and Disorders of Vision, Vision, Ocular, binocular vision, Neurology & Neurosurgery, Psychology and Cognitive Sciences, Neurosciences, eye diseases, Binocular, Brain Disorders, Mice, Inbred C57BL, 030104 developmental biology, Visual cortex, Monocular, Space Perception, Sensory Deprivation, Neuroscience, Binocular vision, 030217 neurology & neurosurgery, Photic Stimulation

Abstract

Study of the neural deficits caused by mismatched binocular vision in early childhood has predominantly focused on circuits in the primary visual cortex (V1). Recent evidence has revealed that neurons in mouse dorsolateral geniculate nucleus (dLGN) can undergo rapid ocular dominance plasticity following monocular deprivation (MD). It remains unclear, however, whether the long-lasting deficits attributed to MD during the critical period originate in the thalamus. Usingin vivotwo-photon Ca2+imaging of dLGN afferents in superficial layers of V1 in female and male mice, we demonstrate that 14 d MD during the critical period leads to a chronic loss of binocular dLGN inputs while sparing response strength and spatial acuity. Importantly, MD leads to profoundly mismatched visual tuning properties in remaining binocular dLGN afferents. Furthermore, MD impairs binocular modulation, reducing facilitation of responses of both binocular and monocular dLGN inputs during binocular viewing. As predicted by our findings in thalamic inputs, Ca2+imaging from V1 neurons revealed spared spatial acuity but impaired binocularity in L4 neurons. V1 L2/3 neurons in contrast displayed deficits in both binocularity and spatial acuity. Our data demonstrate that critical-period MD produces long-lasting disruptions in binocular integration beginning in early binocular circuits in dLGN, whereas spatial acuity deficits first arise from circuits further downstream in V1. Our findings indicate that the development of normal binocular vision and spatial acuity depend upon experience-dependent refinement of distinct stages in the mammalian visual system.SIGNIFICANCE STATEMENTAbnormal binocular vision and reduced acuity are hallmarks of amblyopia, a disorder that affects 2%–5% of the population. It is widely thought that the neural deficits underlying amblyopia begin in the circuits of primary visual cortex. Usingin vivotwo-photon calcium imaging of thalamocortical axons in mice, we show that depriving one eye of input during a critical period in development chronically impairs binocular integration in thalamic inputs to primary visual cortex. In contrast, visual acuity is spared in thalamic inputs. These findings shed new light on the role for developmental mechanisms in the thalamus in establishing binocular vision and may have critical implications for amblyopia.

Published

2020

13. Imaging the dynamic recruitment of monocytes to the blood-brain barrier and specific brain regions during Toxoplasma gondii infection

Author

Chelsie Lo, Melissa B. Lodoen, Dario X. Figueroa Velez, Evelyn M. Hoover, Christine A. Schneider, Sunil P. Gandhi, Omid Vadpey, Ricardo Azevedo, and Cuong J Tran

Subjects

Male, CCR2, Inbred C57BL, blood–brain barrier, Monocytes, Mice, CX3CR1, Receptors, Antigens, Ly, CNS infection, Multidisciplinary, biology, Brain, Biological Sciences, Foodborne Illness, medicine.anatomical_structure, Infectious Diseases, Blood-Brain Barrier, monocyte, Female, medicine.symptom, Infection, Infiltration (medical), Toxoplasmosis, LPS, Receptors, CCR2, CX3C Chemokine Receptor 1, Toxoplasma gondii, Inflammation, Blood–brain barrier, Vaccine Related, Parenchyma, parasitic diseases, medicine, Animals, Antigens, Animal, Monocyte, Prevention, Neurosciences, blood-brain barrier, medicine.disease, biology.organism_classification, Mice, Inbred C57BL, Disease Models, Animal, Emerging Infectious Diseases, Ly, Immunology, Disease Models

Abstract

Brain infection by the parasite Toxoplasma gondii in mice is thought to generate vulnerability to predation by mechanisms that remain elusive. Monocytes play a key role in host defense and inflammation and are critical for controlling T. gondii . However, the dynamic and regional relationship between brain-infiltrating monocytes and parasites is unknown. We report the mobilization of inflammatory (CCR2 + Ly6C hi ) and patrolling (CX3CR1 + Ly6C lo ) monocytes into the blood and brain during T. gondii infection of C57BL/6J and CCR2 RFP/+ CX3CR1 GFP/+ mice. Longitudinal analysis of mice using 2-photon intravital imaging of the brain through cranial windows revealed that CCR2-RFP monocytes were recruited to the blood–brain barrier (BBB) within 2 wk of T. gondii infection, exhibited distinct rolling and crawling behavior, and accumulated within the vessel lumen before entering the parenchyma. Optical clearing of intact T. gondii -infected brains using iDISCO + and light-sheet microscopy enabled global 3D detection of monocytes. Clusters of T. gondii and individual monocytes across the brain were identified using an automated cell segmentation pipeline, and monocytes were found to be significantly correlated with sites of T. gondii clusters. Computational alignment of brains to the Allen annotated reference atlas [E. S. Lein et al., Nature 445:168–176 (2007)] indicated a consistent pattern of monocyte infiltration during T. gondii infection to the olfactory tubercle, in contrast to LPS treatment of mice, which resulted in a diffuse distribution of monocytes across multiple brain regions. These data provide insights into the dynamics of monocyte recruitment to the BBB and the highly regionalized localization of monocytes in the brain during T. gondii CNS infection.

Published

2019

14. Development of a Chimeric Model to Study and Manipulate Human Microglia In Vivo

Author

Karla Echeverria, Mahshad Kolahdouzan, Christel Claes, Amanda McQuade, Robert C. Spitale, Taylor Nakayama, Hayk Davtyan, Jonathan Hasselmann, Morgan A. Coburn, Brian J. Cummings, Luke M. Healy, Ricardo Azevedo, Mathew Blurton-Jones, Sepideh Kiani Shabestari, Dario X. Figueroa Velez, Whitney England, Nicole G. Coufal, Claudia Z. Han, Christina H. Tu, Christopher K. Glass, and Sunil P. Gandhi

Subjects

0301 basic medicine, Induced Pluripotent Stem Cells, Gene Expression, Mice, Transgenic, Plaque, Amyloid, Biology, Transcriptome, 03 medical and health sciences, Chimera (genetics), Mice, 0302 clinical medicine, Alzheimer Disease, medicine, Animals, Humans, Transplantation Chimera, Amyloid beta-Peptides, Microglia, General Neuroscience, Macrophage Colony-Stimulating Factor, Neurodegeneration, Hematopoietic Stem Cell Transplantation, Brain, Granulocyte-Macrophage Colony-Stimulating Factor, Cell Differentiation, Gene signature, medicine.disease, Transplantation, Haematopoiesis, Disease Models, Animal, 030104 developmental biology, medicine.anatomical_structure, nervous system, Thrombopoietin, Stem cell, Neuroscience, 030217 neurology & neurosurgery

Abstract

iPSC-derived microglia offer a powerful tool to study microglial homeostasis and disease-associated inflammatory responses. Yet, microglia are highly sensitive to their environment, exhibiting transcriptomic deficiencies when kept in isolation from the brain. Furthermore, species-specific genetic variations demonstrate that rodent microglia fail to fully recapitulate the human condition. To address this, we developed an approach to study human microglia within a surrogate brain environment. Transplantation of iPSC-derived hematopoietic-progenitors into the postnatal brain of humanized, immune-deficient mice results in context-dependent differentiation into microglia and other CNS macrophages, acquisition of an ex vivo human microglial gene signature, and responsiveness to both acute and chronic insults. Most notably, transplanted microglia exhibit robust transcriptional responses to Aβ-plaques that only partially overlap with that of murine microglia, revealing new, human-specific Aβ-responsive genes. We therefore have demonstrated that this chimeric model provides a powerful new system to examine the in vivo function of patient-derived and genetically modified microglia.

Published

2019

15. Critical-Period Visual Deprivation Disrupts Binocular Integration but Spares Spatial Acuity in the Geniculocortical Pathway

Author

Dario X. Figueroa Velez, John P. Peach, Karim Abdelaal, Carey Y. L. Huh, Sunil P. Gandhi, Charless C. Fowlkes, Kirstie J. Salinas, Jack Zeitoun, and Diyue Gu

Subjects

Monocular, Visual acuity, genetic structures, Thalamus, Biology, eye diseases, Monocular deprivation, Visual cortex, medicine.anatomical_structure, Geniculate, Excitatory postsynaptic potential, medicine, medicine.symptom, Neuroscience, Binocular vision

Abstract

Monocular deprivation (MD) during the juvenile critical period leads to long-lasting impairments in binocular function and visual acuity. The site of these changes has been widely considered to be cortical. However, recent evidence indicates that binocular integration may first occur in the dorsolateral geniculate nucleus of the thalamus (dLGN), raising the question of whether MD during the critical period may produce long-lasting deficits in dLGN binocular integration. Using in vivo two-photon Ca2+ imaging of dLGN afferents and excitatory neurons in superficial layers of primary visual cortex (V1), we demonstrate that critical-period MD leads to a persistent and selective loss of binocular dLGN inputs, while leaving spatial acuity in the thalamocortical pathway intact. Despite being few in number, binocular dLGN boutons display remarkably robust visual responses, on average twice stronger than monocular boutons, and their responses are exquisitely well-matched between the eyes. To our surprise, we found that MD leads to a profound binocular mismatch of response amplitude, spatial frequency and orientation tuning detected at the level of single thalamocortical synapses. In comparison, V1 neurons display deficits in both binocular integration and spatial acuity following MD. Our data provide the most compelling evidence to date demonstrating that following critical-period MD, binocular deficits observed at the level of V1 may at least in part originate from dLGN binocular dysfunction, while spatial acuity deficits arise from cortical circuits. These findings highlight a hitherto unknown role of the thalamus as a site for developmental refinement of binocular vision.

Published

2018

16. Inhibitory Neuron Transplantation into Adult Visual Cortex Creates a New Critical Period that Rescues Impaired Vision

Author

Melissa F. Davis, Sunil P. Gandhi, Dario X. Figueroa Velez, Mathew C. Carathedathu, Roblen P. Guevarra, Mariyam Habeeb, and Michael C. Yang

Subjects

Aging, Visual perception, genetic structures, Ganglionic eminence, Neuroscience(all), Ocular dominance, Neuroplasticity, medicine, Psychology, Animals, Sensory deprivation, Vision, Ocular, Visual Cortex, Critical period, Neurons, Neurology & Neurosurgery, Neuronal Plasticity, Critical Period, Psychological, General Neuroscience, Neurosciences, Neural Inhibition, eye diseases, Dominance, Ocular, Mice, Inbred C57BL, Transplantation, Visual cortex, medicine.anatomical_structure, Evoked Potentials, Visual, Cognitive Sciences, Sensory Deprivation, Neuroscience

Abstract

© 2015 Elsevier Inc. The maturation of inhibitory circuits in juvenile visual cortex triggers a critical period in the development of the visual system. Although several manipulations of inhibition can alter the timing of the critical period, none have demonstrated the creation of a new critical period in adulthood. We developed a transplantation method to reactivate critical period plasticity in the adult visual cortex. Transplanted embryonic inhibitory neurons from the medial ganglionic eminence reinstate ocular dominance plasticity inadult recipients. Transplanted inhibitory cells develop cell-type-appropriate molecular characteristics and visually evoked responses. In adult mice impaired by deprivation during the juvenile critical period, transplantation also recovers both visual cortical responses and performance on a behavioral test of visual acuity. Plasticity and recovery are induced when the critical period would have occurred in the donor animal. These results reveal that the focal reactivation of visual cortical plasticity using inhibitory cell transplantation creates a new critical period that restores visual perception after childhood deprivation. Davis etal. demonstrate the creation of a new critical period using inhibitory neuron transplantation into adult visual cortex. Transplantation in adulthood reverses visual impairment caused by deprivation during the juvenile critical period.

Published

2015

17. Subventricular zone/white matter microglia reconstitute the empty adult microglial niche in a dynamic wave

Author

Lindsay A Hohsfield, Allison R Najafi, Yasamine Ghorbanian, Neelakshi Soni, Joshua Crapser, Dario X Figueroa Velez, Shan Jiang, Sarah E Royer, Sung Jin Kim, Caden M Henningfield, Aileen Anderson, Sunil P Gandhi, Ali Mortazavi, Matthew A Inlay, and Kim N Green

Subjects

microglia, depletion, CSF1R, repopulation, white matter, Medicine, Science, Biology (General), QH301-705.5

Abstract

Microglia, the brain’s resident myeloid cells, play central roles in brain defense, homeostasis, and disease. Using a prolonged colony-stimulating factor 1 receptor inhibitor (CSF1Ri) approach, we report an unprecedented level of microglial depletion and establish a model system that achieves an empty microglial niche in the adult brain. We identify a myeloid cell that migrates from the subventricular zone and associated white matter areas. Following CSF1Ri, these amoeboid cells migrate radially and tangentially in a dynamic wave filling the brain in a distinct pattern, to replace the microglial-depleted brain. These repopulating cells are enriched in disease-associated microglia genes and exhibit similar phenotypic and transcriptional profiles to white-matter-associated microglia. Our findings shed light on the overlapping and distinct functional complexity and diversity of myeloid cells of the CNS and provide new insight into repopulating microglia function and dynamics in the mouse brain.

Published

2021