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Home NEWS Science News Health

Microglia Shape Developing Cortical Blood Vessels via PD-1 Signaling

Bioengineer by Bioengineer
July 16, 2026
in Health
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New blood vessels flood the developing brain, then must be sculpted into a functional network. In the cortex, this pruning depends on selective elimination of redundant connections, but the cellular command center behind vascular refinement has remained only partly understood. A new study now points to microglia—the brain’s immune sentinels—as active architects of cerebrovascular pruning during postnatal development.

Using live visualization in the frontal cortex of postnatal day 11 mice, researchers tracked how microglia behave around forming blood vessels. They observed that microglia do not merely associate with vasculature; instead, they progressively migrate toward vessels as development proceeds. As vessel remodeling advances, microglia become enriched at sites where pruning occurs, suggesting a causal role rather than passive surveillance.

To test function, the team manipulated microglia–vessel interactions and assessed vascular outcomes. Intervening in microglial activity altered the extent of vessel elimination, consistent with the idea that microglia mediate pruning to refine the emerging vascular map. The results connect microglial behavior directly to the efficiency and organization of the developing cortical circulation.

Central to the mechanism is an immune signaling pathway previously linked to neuronal synaptic refinement: PD-L1 and its receptor PD-1. The study identifies PD-L1–PD-1 signaling as a regulator of microglia-driven vascular pruning. When this axis was disrupted, pruning was impaired, indicating that immune checkpoint-like communication can shape vascular architecture in the developing brain.

The authors further implicate a specific molecular source from microglia. They report that microglial CD5L secretion promotes the PD-1–dependent pruning program. In other words, microglia release CD5L, engage PD-1 signaling through PD-L1 interactions, and thereby influence which vessels persist and which are eliminated.

Collectively, the work reframes cerebrovascular pruning as a neuroimmune-guided developmental process. By showing that microglia actively target redundant vasculature and by defining a PD-L1–PD-1/CD5L pathway, the study provides mechanistic evidence for how immune cells can tune vascular networks to match developing brain circuitry.

Beyond development, the findings raise broader questions about whether similar immune checkpoint signaling contributes to abnormal vascular remodeling in disease, where pruning can be either excessive or insufficient. For now, the study delivers a clear developmental role: microglia help determine what the brain keeps growing and what it discards.

DOI: https://doi.org/10.1038/s41593-026-02378-x

Article Title: Microglia prune developing cortical blood vessels through PD-1 signaling.

Article References: Zhang, M., Wang, Y., Yang, R. et al. Microglia prune developing cortical blood vessels through PD-1 signaling. Nat Neurosci (2026). https://doi.org/10.1038/s41593-026-02378-x

Image Credits: AI Generated

Tags: cerebrovascular pruning during postnatal brain developmentimmune pathways regulating cerebrovascular developmentlive imaging of microglia in developing brainmicroglia as active participantsmicroglia migration toward blood vessels during developmentmicroglia role in cortical blood vessel developmentmicroglia-mediated vascular refinement in cortexmicroglia-vessel interactions in cortical blood vessel remodelingmicroglial contribution to neural circuit formation via blood vesselsPD-L1 and PD-1 signaling in microglia function

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