RNA-Seq Analysis of Microglia Reveals Time-Dependent Activation of Specific Genetic Programs following Spinal Cord Injury

Noristani, Harun N.; Gerber, Yannick Nicolas; Sabourin, Jean-Charles; Corre, Marine Le; Lonjon, Nicolas; Mestre‐Francés, Nadine; Hirbec, Hélène; Perrin, Florence E.

doi:10.3389/fnmol.2017.00090

Cited by 61 publications

(96 citation statements)

References 78 publications

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“…Table shows some features of aberrant glial cells, including astrocytes or microglia, abnormally‐expressing markers from different cell lineages have been also reported in Alzheimer's disease, Huntington's disease, central nervous system acute lesions and aging, as well as glioma, brain ischemia and trauma, further suggesting the phenotypic switch is strongly associated with inflammation and tissue remodeling after damage.…”

Section: Phenotypic Heterogeneity Of Astrocytes In Als and Other Neurmentioning

confidence: 80%

“…expressing markers from different cell lineages have been also reported in Alzheimer's disease, 75 Huntington's disease, 76 central nervous system acute lesions [77][78][79] and aging, 74,80 as well as glioma, 56,57,81 brain ischemia and trauma, 78,79,82 further suggesting the phenotypic switch is strongly associated with inflammation and tissue remodeling after damage. Compared with microglia/macrophages, astrocytes have been regarded to retain fewer phagocytic abilities.…”

Section: Phenotypic Heterogeneity Of Astrocytes In Als and Other Neurmentioning

confidence: 86%

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Phenotypic heterogeneity of astrocytes in motor neuron disease

Trías

Barbeito

Yamanaka

2018

Clinical & Exp Neuroim

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Accumulating evidence has shown that astrocytes do not just support the function of neurons, but play key roles in maintaining the brain environment in health and disease. Contrary to the traditional understanding of astrocytes as static cells, reactive astrocytes possess more diverse functions and phenotypes than previously predicted. In the present focused review, we summarize the evidence showing that astrocytes are playing profound roles in the disease process of amyotrophic lateral sclerosis. Aberrantly activated astrocytes in amyotrophic lateral sclerosis rodents express microglial molecular markers and provoke toxicities to accelerate disease progression. In addition, TIR domain–containing adapter protein–inducing interferon‐β‐dependent innate immune pathway in astrocytes also has a novel function in terminating glial activation and neuroinflammation. Furthermore, heterogeneity in phenotypes and functions of astrocytes are also observed in various disease conditions, such as other neurodegenerative diseases, ischemia, aging and acute lesions in the central nervous system. Through accumulating knowledge of the phenotypic and functional diversity of astrocytes, these cells will become more attractive therapeutic targets for neurological diseases.

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Section: Phenotypic Heterogeneity Of Astrocytes In Als and Other Neurmentioning

confidence: 80%

Section: Phenotypic Heterogeneity Of Astrocytes In Als and Other Neurmentioning

confidence: 86%

Phenotypic heterogeneity of astrocytes in motor neuron disease

Trías

Barbeito

Yamanaka

2018

Clinical & Exp Neuroim

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“…In a study of facial nucleus axotomy, the authors also related the observed microglial phenotype (134) to the DAM phenotype, as well as to a phenotype found in the Ck-p25 model (109): 72 genes were regulated in common between all three studies representing almost 75% of all genes upregulated in the facial nucleus axotomy model. Interestingly, in an SCI transcriptomic study, a profile of microglia reminiscent of the CD11c+ phenotype was identified (with upregulation of Gpnmb, Spp1, Lpl, Apoe, Igf1, Lgals3, and Itgax among others) and persisted in a full transection model, whereas it contracted concomitantly to recovery in a hemisection model (135), indicative of the transitory nature of this subset. Conversely, in TBI, the microglial signature was further from the CD11c+ microglia signature, although Itgax was among the upregulated genes 14 and 60 days post-injury, possibly indicating once again a dilution of the signature in all microglia (136).…”

Section: Stroke Ischemia and Injurymentioning

confidence: 99%

Protective Microglial Subset in Development, Aging, and Disease: Lessons From Transcriptomic Studies

2020

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Microglial heterogeneity has been the topic of much discussion in the scientific community. Elucidation of their plasticity and adaptability to disease states triggered early efforts to characterize microglial subsets. Over time, their phenotypes, and later on their homeostatic signature, were revealed, through the use of increasingly advanced transcriptomic techniques. Recently, an increasing number of these "microglial signatures" have been reported in various homeostatic and disease contexts. Remarkably, many of these states show similar overlapping microglial gene expression patterns, both in homeostasis and in disease or injury. In this review, we integrate information from these studies, and we propose a unique subset, for which we introduce a core signature, based on our own research and reports from the literature. We describe that this subset is found in development and in normal aging as well as in diverse diseases. We discuss the functions of this subset as well as how it is induced.

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“…As the brain develops, immature microglial cells differentiate as they continue a complex lifelong interplay with neuronal cells, downregulating signal pathways such as C-X-X motif chemokine ligand 12 (CXCL12) and C-X-X motif chemokine receptor 4 (CXCR4), and upregulating others [48], to become mature microglia. RNA sequence analysis has provided novel insights into the plasticity of microglia in models of neurodegeneration (e.g., inducing facial nerve axotomy in mice) or inflammation (e.g., inducing spinal cord injury in non-human primate models) [49][50][51]. For instance, an established unique set of genes that are preferentially expressed by aging microglia were found to be enriched in pathologies such as Alzheimer's disease or multiple sclerosis [49].…”

Section: The Developing Brain As a Unique Tumor Sitementioning

confidence: 99%

Towards Immunotherapy for Pediatric Brain Tumors

Wang

Bandopadhayay

Jenkins

2019

Trends in Immunology

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Pediatric brain tumors are the leading cause of childhood cancer-related death. Immunotherapy is a powerful new approach for treating some refractory cancers; applying this 'fourth pillar' of cancer treatment to pediatric brain tumors is an exciting but challenging prospect. This review offers new perspectives on moving towards successful immunotherapy for pediatric brain tumors, focusing on pediatric high-grade glioma (HGG), a subgroup with universally poor outcomes. We cover chimeric antigen receptor T cell (CAR-T) therapy, vaccine therapy, and checkpoint inhibition in this context, and focus on the need for intimately understanding the growing brain and its immune system. We highlight the challenges associated with the application of immunotherapy in pediatric neuro-oncology, as well as the tissue-specific challenges to be overcome, to achieve improved outcomes. Immunotherapy: A New Approach for Pediatric Brain Tumors Recent advances in cancer immunotherapy have improved outcomes for several human cancers, and in some cases have produced dramatic responses in patients refractory to all other conventional modes of treatment [1-3]. Although the concept of strengthening, redirecting, or generating an immune response against malignancy is by no means new, cancer immunotherapy has only recently received worldwide attention. Immunotherapy has demonstrated remarkable success in improving overall survival in Phase II-III trials in tumor subtypes such as melanoma and leukemia [1,4]. This novel approach has been a welcome addition to the oncologist's conventional armamentarium of surgery, chemotherapy, and radiation, especially in the relapsed and/or refractory disease setting. This rapid advancement in the immuno-oncology field occurs in a timely manner for childhood brain tumors, which urgently require a new approach. Tumors of the central nervous system (CNS) are the most common solid tumor of childhood, and represent the leading cause of childhood cancer-related death [5]. Although survival rates for childhood cancers overall have markedly improved over recent decades, outcomes in pediatric CNS tumors have lagged behind the dramatic gains achieved in hematological cancers. The overall survival rate in childhood acute lymphoblastic leukemia now exceeds 90% at 5 years [6]. In stark contrast, children with pediatric high-grade glioma (HGG; see Glossary), including diffuse midline glioma (DMG), and glioblastoma multiforme (GBM), have a dismal 5 year overall survival of b20% [6]. This occurs despite recent increased knowledge of the genomics of pediatric HGG and how this diverges markedly from adult brain tumors [7], and multiple trials of differing combinations of radiation, chemotherapeutic agents, and novel adjuvants. Furthermore, given that current conventional treatments involve irradiation of the brain, the few survivors of pediatric brain tumors are often left with devastating morbidities, including endocrine disease, psychiatric, cognitive and developmental disorders, and neurological disease, as well as a high i...

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RNA-Seq Analysis of Microglia Reveals Time-Dependent Activation of Specific Genetic Programs following Spinal Cord Injury

Cited by 61 publications

References 78 publications

Phenotypic heterogeneity of astrocytes in motor neuron disease

Phenotypic heterogeneity of astrocytes in motor neuron disease

Protective Microglial Subset in Development, Aging, and Disease: Lessons From Transcriptomic Studies

Towards Immunotherapy for Pediatric Brain Tumors

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