Devi Santhosh scite author profile

Kumar

et al. 2017

Developmental Cell

Summary Intimate communication between neural and vascular cells is critical for normal brain development and function. Germinal matrix (GM), a key primordium for the brain reward circuitry, is unique among brain regions for its distinct pace of angiogenesis and selective vulnerability to hemorrhage during development. A major neonatal condition, GM hemorrhage can lead to cerebral palsy, hydrocephalus, and mental retardation. Here we identify a brain region-specific neural progenitor-based signaling pathway dedicated to regulating GM vessel development. This pathway consists of cell surface sphingosine-1-phosphate receptors, an intracellular cascade including Gα co-factor Ric8a and p38 MAPK, and target gene integrin β8, which in turn regulates vascular TGFβ signaling. These findings provide novel insights into region-specific specialization of neurovascular communication, with special implications for deciphering potent early-life endocrine as well as potential gut microbiota impacts on brain reward circuitry. They also identify tissue-specific molecular targets for GM hemorrhage intervention.

Regulation of the nascent brain vascular network by neural progenitors

Mechanisms of Development

Huang

2015

Neural progenitors are central players in the development of the brain neural circuitry. They not only produce the diverse neuronal and glial cell types in the brain, but also guide their migration in this process. Recent evidence indicates that neural progenitors also play a critical role in the development of the brain vascular network. At an early stage, neural progenitors have been found to facilitate the ingression of blood vessels from outside the neural tube, through VEGF and canonical Wnt signaling. Subsequently, neural progenitors directly communicate to endothelial cells to stabilize nascent brain vessels, in part through down-regulating Wnt pathway activity. Furthermore, neural progenitors promote nascent brain vessel integrity, through integrin αvβ8-dependent TGFβ signaling. In this review, we will discuss the evidence for, as well as questions that remain, regarding these novel roles of neural progenitors and the underlying mechanisms in their regulation of the nascent brain vascular network.

Harnessing region-specific neurovascular signaling to promote germinal matrix vessel maturation and hemorrhage prevention

Sherman

Chowdhury

et al. 2019

Germinal matrix hemorrhage (GMH), affecting about 1 in 300 births, is a major perinatal disease with lifelong neurological consequences. Yet despite advances in neonatal medicine, there is no effective intervention. GMH is characterized by localized bleeding in the germinal matrix (GM), due to inherent vessel fragility unique to this developing brain region. Studies have shown that reduced TGFβ signaling contributes to this vascular immaturity. We have previously shown that a region-specific G-protein-coupled receptor pathway in GM neural progenitor cells regulates integrin β8, a limiting activator of pro-TGFβ. In this study, we use mice to test whether this regional pathway can be harnessed for GMH intervention. We first examined the endogenous dynamics of this pathway and found that it displays specific patterns of activation. We then investigated the functional effects of altering these dynamics by chemogenetics and found that there is a narrow developmental window during which this pathway is amenable to manipulation. Although high-level activity in this time window interferes with vessel growth, moderate enhancement promotes vessel maturation without compromising growth. Furthermore, we found that enhancing the activity of this pathway in a mouse model rescues all GMH phenotypes. Altogether, these results demonstrate that enhancing neurovascular signaling through pharmacological targeting of this pathway may be a viable approach for tissue-specific GMH intervention. They also demonstrate that timing and level are likely two major factors crucial for success. These findings thus provide critical new insights into both brain neurovascular biology and the intervention of GMH.

A Tie2‐driven BAC‐TRAP transgenic line for in vivo endothelial gene profiling

Huang

2016

Genesis

Recent technological innovations including bacterial artificial chromosome-based translating ribosome affinity purification (BAC-TRAP) have greatly facilitated analysis of cell type-specific gene expression in vivo, especially in the nervous system. To better study endothelial gene expression in vivo, we have generated a BAC-TRAP transgenic mouse line where the L10a ribosomal subunit is tagged with EGFP and placed under the control of the endothelium-specific Tie2 (Tek) promoter. We show that transgene expression in this line is widely, but specifically, detected in endothelial cells in several brain regions throughout pre- and postnatal development, as well as in other organs. We also show that this line results in highly significant enrichment of endothelium-specific mRNAs from brain tissues at different stages. This BAC-TRAP line therefore provides a useful genetic tool for in vivo endothelial gene profiling under various developmental, physiological, and pathological conditions.

Monomeric amyloid-β inhibits microglial inflammatory activity in the brain via an APP/heterotrimeric G protein-mediated pathway

Kwon¹,

Santhosh²,

Huang³

2023

Preprint

SUMMARYMicroglia, the resident immune cell of the brain, play critical roles in brain development, function, and disease. However, how microglial activity is regulated in this process remains to be elucidated. Here we report an amyloid precursor protein (APP) and heterotrimeric G protein-mediated pathway that negatively regulates microglial inflammatory activation during cerebral cortex development. Disruption of this pathway results in dysregulated microglial activity, excessive extracellular matrix proteinase production, cortical basement membrane breach, and laminar assembly disruption. We further show that this pathway is activated by amyloid β (Aβ), the cleavage product of APP that accumulates in large quantities as plaques in the Alzheimer’s disease brain. Specifically, we find Aβ monomers potently suppress inflammatory cytokine transcription and secretion by brain microglia, in an APP and heterotrimeric G protein-dependent manner. These results discover a previously unknown activity of Aβ as a negative regulator of brain microglia as well as a new pathway that mediates the signal transduction. They shed new light on the cell-cell communication mechanisms that regulate brain immune homeostasis and may facilitate further insight into Alzheimer’s disease pathogenesis.