Microglia/macrophages as target to prevent intracerebral hemorrhage in KRAS mutation-induced brain arteriovenous malformations
University Of Texas Hlth Sci Ctr Houston, Houston TX
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Abstract
Project Summary/Abstract Brain arteriovenous malformation (bAVM) patients have a 50% risk of intracerebral hemorrhage (ICH) which carries a high risk of severe morbidity and mortality. Although a surgical attempt is a conventional treatment for the bAVM, the surgery for critical bAVM is associated with significant complications such as intraoperative hemorrhage or death. Our long-term goal is to identify a preventative strategy for ICH in bAVM patients. The inciting pathophysiology leading to bAVM rupture is unknown. Studies have shown that the presence of a bAVM is highly correlated with local inflammation of intranidal and surrounding brain parenchyma. Immunohistochemistry studies have identified dense concentrations of brain microglia and blood monocyte- derived macrophages (we refer to them as Mï) surrounding the unruptured human bAVM. Meanwhile, clinical studies found that 62% of human sporadic bAVM patients harbored KRAS mutations in vascular endothelial cells (ECs). Here we found that ECs carrying KRAS mutation (KRAS-EC) induced inflammatory responses toward cultured Mï that in turn disrupts EC junctions. This suggests that Mï-mediated inflammation drives bAVM destabilization that may lead to bAVM rupture/ICH. To explore how KRAS-EC alter Mï phenotype and destabilize bAVM, we established a novel bAVM/ICH mouse model that uses the ECs-specific AAV/BR1 to deliver mutant KRAS (AAV-KRASG12V) into brain ECs (bEC). The KRASG12V/bEC mouse recapitulates human bAVM pathology, including tangled vessels, incomplete mural cell coverage, spontaneous ICH, and neurological deficits (Park 2021 Ann Neurol). In KRASG12V/bEC mouse, we showed that the number of Iba-1+ Mïï are increased around unruptured bAVM. The mRNA or protein levels for inflammatory cytokines, Proteolytic enzymes, angiogenic mediator, and adhesion molecule are increased in KRASG12V/bEC mice and in KRAS-EC themselves. Furthermore, KRASG12V/bEC mice treated with clodronate liposome (to deplete Mï) or minocycline reduces early microbleeds. Our preliminary study and existing literature strongly supporting the notion that the activated Mï- mediated inflammation drives bAVM destabilization that may lead to bAVM rupture/ICH. In this proposal, we will test our hypothesis that KRAS-EC recruit and activate Mï within bAVM territory and that these activated Mï in turn exacerbate the (peri)vascular damage causing bAVM rupture/ICH and that inhibition of Mï can avert/delay this process. In Aim 1, we will determine the mechanism causing Mïï activation and BBB disruption in bAVM. In Aim 2, we will evaluate the clinical relevance of Mï in bAVM rupture and ICH. We expect that the successful completion of this preclinical study will uncover a causative role of Mïï in bAVM rupture and ICH and will provide evidence to test the potential for Mï modulation in the prevention of bAVM-associated ICH. Our proposal has the potential for broad implications as Mï are commonly involved in most cerebrovascular diseases.
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