ABSTRACT
Zika virus (ZIKV) has become a public health threat due to its global transmission and link to severe congenital disorders. The host immune responses to ZIKV infection have not been fully elucidated, and effective therapeutics are not currently available. Herein, we demonstrated that cholesterol-25-hydroxylase (CH25H) was induced in response to ZIKV infection and that its enzymatic product, 25-hydroxycholesterol (25HC), was a critical mediator of host protection against ZIKV. Synthetic 25HC addition inhibited ZIKV infection in vitro by blocking viral entry, and treatment with 25HC reduced viremia and conferred protection against ZIKV in mice and rhesus macaques. 25HC suppressed ZIKV infection and reduced tissue damage in human cortical organoids and the embryonic brain of the ZIKV-induced mouse microcephaly model. Our findings highlight the protective role of CH25H during ZIKV infection and the potential use of 25HC as a natural antiviral agent to combat ZIKV infection and prevent ZIKV-associated outcomes, such as microcephaly.
Subject(s)
Antiviral Agents/pharmacology , Hydroxycholesterols/pharmacology , Microcephaly/virology , Zika Virus Infection/complications , Animals , Brain/drug effects , Disease Models, Animal , Fluorescent Antibody Technique , Humans , Macaca mulatta , Mice , Microscopy, Confocal , Virus Internalization/drug effects , Zika Virus/drug effects , Zika Virus/physiologyABSTRACT
Neural progenitor cells within the cerebral cortex undergo a characteristic switch between symmetric self-renewing cell divisions early in development and asymmetric neurogenic divisions later. Yet, the mechanisms controlling this transition remain unclear. Previous work has shown that early but not late neural progenitor cells (NPCs) endogenously express the autism-linked transcription factor Foxp1, and both loss and gain of Foxp1 function can alter NPC activity and fate choices. Here, we show that premature loss of Foxp1 upregulates transcriptional programs regulating angiogenesis, glycolysis, and cellular responses to hypoxia. These changes coincide with a premature destabilization of HIF-1α, an elevation in HIF-1α target genes, including Vegfa in NPCs, and precocious vascular network development. In vitro experiments demonstrate that stabilization of HIF-1α in Foxp1-deficient NPCs rescues the premature differentiation phenotype and restores NPC maintenance. Our data indicate that the endogenous decline in Foxp1 expression activates the HIF-1α transcriptional program leading to changes in the tissue environment adjacent to NPCs, which, in turn, might alter their self-renewal and neurogenic capacities.
Subject(s)
Cerebral Cortex , Forkhead Transcription Factors , Hypoxia-Inducible Factor 1, alpha Subunit , Neural Stem Cells , Repressor Proteins , Signal Transduction , Hypoxia-Inducible Factor 1, alpha Subunit/metabolism , Hypoxia-Inducible Factor 1, alpha Subunit/genetics , Forkhead Transcription Factors/metabolism , Forkhead Transcription Factors/genetics , Neural Stem Cells/metabolism , Neural Stem Cells/cytology , Animals , Mice , Cerebral Cortex/metabolism , Cerebral Cortex/cytology , Repressor Proteins/metabolism , Repressor Proteins/genetics , Neovascularization, Physiologic/genetics , Cell Differentiation/genetics , Vascular Endothelial Growth Factor A/metabolism , Vascular Endothelial Growth Factor A/genetics , Neurogenesis/genetics , Glycolysis , AngiogenesisABSTRACT
Telencephalic organoids generated from human pluripotent stem cells (hPSCs) are a promising system for studying the distinct features of the developing human brain and the underlying causes of many neurological disorders. While organoid technology is steadily advancing, many challenges remain, including potential batch-to-batch and cell-line-to-cell-line variability, and structural inconsistency. Here, we demonstrate that a major contributor to cortical organoid quality is the way hPSCs are maintained prior to differentiation. Optimal results were achieved using particular fibroblast-feeder-supported hPSCs rather than feeder-independent cells, differences that were reflected in their transcriptomic states at the outset. Feeder-supported hPSCs displayed activation of diverse transforming growth factor ß (TGFß) superfamily signaling pathways and increased expression of genes connected to naive pluripotency. We further identified combinations of TGFß-related growth factors that are necessary and together sufficient to impart broad telencephalic organoid competency to feeder-free hPSCs and enhance the formation of well-structured brain tissues suitable for disease modeling.
Subject(s)
Organoids , Pluripotent Stem Cells , Cell Differentiation/physiology , Humans , Organoids/metabolism , Pluripotent Stem Cells/metabolism , Telencephalon/metabolism , Transforming Growth Factor beta/metabolismABSTRACT
Brain organoids represent a powerful tool for studying human neurological diseases, particularly those that affect brain growth and structure. However, many diseases manifest with clear evidence of physiological and network abnormality in the absence of anatomical changes, raising the question of whether organoids possess sufficient neural network complexity to model these conditions. Here, we explore the network-level functions of brain organoids using calcium sensor imaging and extracellular recording approaches that together reveal the existence of complex network dynamics reminiscent of intact brain preparations. We demonstrate highly abnormal and epileptiform-like activity in organoids derived from induced pluripotent stem cells from individuals with Rett syndrome, accompanied by transcriptomic differences revealed by single-cell analyses. We also rescue key physiological activities with an unconventional neuroregulatory drug, pifithrin-α. Together, these findings provide an essential foundation for the utilization of brain organoids to study intact and disordered human brain network formation and illustrate their utility in therapeutic discovery.
Subject(s)
Brain/physiopathology , Epilepsy/physiopathology , Neurons , Adult , Benzothiazoles/pharmacology , Brain/growth & development , Calcium Signaling , Child, Preschool , Epilepsy/diagnostic imaging , Female , Humans , Induced Pluripotent Stem Cells , Methyl-CpG-Binding Protein 2/genetics , Nerve Net/physiopathology , Neurogenesis/genetics , Neuroimaging , Rett Syndrome/diagnostic imaging , Rett Syndrome/physiopathology , Single-Cell Analysis , Synapses , Toluene/analogs & derivatives , Toluene/pharmacology , TranscriptomeABSTRACT
The human cerebral cortex possesses distinct structural and functional features that are not found in the lower species traditionally used to model brain development and disease. Accordingly, considerable attention has been placed on the development of methods to direct pluripotent stem cells to form human brain-like structures termed organoids. However, many organoid differentiation protocols are inefficient and display marked variability in their ability to recapitulate the three-dimensional architecture and course of neurogenesis in the developing human brain. Here, we describe optimized organoid culture methods that efficiently and reliably produce cortical and basal ganglia structures similar to those in the human fetal brain in vivo. Neurons within the organoids are functional and exhibit network-like activities. We further demonstrate the utility of this organoid system for modeling the teratogenic effects of Zika virus on the developing brain and identifying more susceptibility receptors and therapeutic compounds that can mitigate its destructive actions.