Targeting the microenvironment in the treatment of arteriovenous malformations

IF 9.2 1区 医学 Q1 PERIPHERAL VASCULAR DISEASE
Caroline T. Seebauer, Benedikt Wiens, Constantin A. Hintschich, Natascha Platz Batista da Silva, Katja Evert, Frank Haubner, Friedrich G. Kapp, Christina Wendl, Kathrin Renner, Christopher Bohr, Thomas Kühnel, Veronika Vielsmeier
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引用次数: 0

Abstract

Extracranial arteriovenous malformations (AVMs) are regarded as rare diseases and are prone to complications such as pain, bleeding, relentless growth, and high volume of shunted blood. Due to the high vascular pressure endothelial cells of AVMs are exposed to mechanical stress. To control symptoms and lesion growth pharmacological treatment strategies are urgently needed in addition to surgery and interventional radiology. AVM cells were isolated from three patients and exposed to cyclic mechanical stretching for 24 h. Thalidomide and bevacizumab, both VEGF inhibitors, were tested for their ability to prevent the formation of circular networks and proliferation of CD31+ endothelial AVM cells. Furthermore, the effect of thalidomide and bevacizumab on stretched endothelial AVM cells was evaluated. In response to mechanical stress, VEGF gene and protein expression increased in patient AVM endothelial cells. Thalidomide and bevacizumab reduced endothelial AVM cell proliferation. Bevacizumab inhibited circular network formation of endothelial AVM cells and lowered VEGF gene and protein expression, even though the cells were exposed to mechanical stress. With promising in vitro results, bevacizumab was used to treat three patients with unresectable AVMs or to prevent regrowth after incomplete resection. Bevacizumab controlled bleeding, pulsation, and pain over the follow up of eight months with no patient-reported side effects. Overall, mechanical stress increases VEGF expression in the microenvironment of AVM cells. The monoclonal VEGF antibody bevacizumab alleviates this effect, prevents circular network formation and proliferation of AVM endothelial cells in vitro. The clinical application of bevacizumab in AVM treatment demonstrates effective symptom control with no side effects.

Graphical abstract

Mechanical stress increases VEGF expression in endothelial AVM cells, possibly causing the VEGF upregulation in the microenvironment of AVM cells. The resulting RAS/RAF/MEK/ERK signaling in leads to progression of fast-flow malformations. The monoclonal VEGF-A antibody bevacizumab alleviates this effect, prevents circular network formation and proliferation of AVM endothelial cells in vitro. Sporadically occurring slow-flow malformations (LMs, VMs) have mutations in TEK or PIK3CA. TEK encodes the endothelial receptor tyrosine kinase TIE2. Sporadic extracranial fast-flow malformations (AVMs) show mutations in KRAS, BRAF and MAP2K1, which encodes the dual specificity mitogen-activated protein kinase MEK1. Combined targeting of the molecular causes of the disease could be key to achieve symptom control and reduce lesion growth. Orange: gain-of-function; Blue, circled with orange: enhanced signaling.

Abstract Image

针对动静脉畸形治疗中的微环境。
颅外动静脉畸形(AVMs)被认为是罕见疾病,容易出现并发症,如疼痛、出血、持续生长和大量分流血液。由于高血管压力,AVMs的内皮细胞暴露于机械应力。为了控制症状和病变生长,除了手术和介入放射学外,还迫切需要药物治疗策略。从三名患者中分离AVM细胞,并将其暴露于循环机械拉伸24小时。沙利度胺和贝伐单抗都是VEGF抑制剂,测试了它们预防环状网络形成和CD31+内皮AVM细胞增殖的能力。此外,还评估了沙利度胺和贝伐单抗对拉伸内皮AVM细胞的影响。在对机械应力的反应中,患者AVM内皮细胞中VEGF基因和蛋白表达增加。沙利度胺和贝伐单抗降低了内皮AVM细胞的增殖。贝伐单抗抑制内皮AVM细胞的环状网络形成,并降低VEGF基因和蛋白质的表达,即使细胞暴露于机械应力。贝伐单抗用于治疗三名不可切除的动静脉畸形患者或防止不完全切除后的再生,具有良好的体外效果。贝伐单抗在八个月的随访中控制了出血、搏动和疼痛,没有患者报告副作用。总的来说,机械应力增加了AVM细胞微环境中VEGF的表达。单克隆VEGF抗体贝伐单抗减轻了这种影响,防止了体外AVM内皮细胞的环状网络形成和增殖。贝伐单抗在AVM治疗中的临床应用证明了有效的症状控制,没有副作用。机械应力增加内皮AVM细胞中VEGF的表达,可能导致AVM细胞微环境中VEGF的上调。由此产生的RAS/RAF/MEK/ERK信号传导导致快速血流畸形的进展。单克隆VEGF-A抗体贝伐单抗减轻了这种影响,防止了体外AVM内皮细胞的环状网络形成和增殖。散发性慢流畸形(LMs、VM)具有TEK或PIK3CA突变。TEK编码内皮受体酪氨酸激酶TIE2。偶发性颅外快速血流畸形(AVMs)显示KRAS、BRAF和MAP2K1突变,MAP2K1编码双特异性丝裂原活化蛋白激酶MEK1。结合靶向该疾病的分子原因可能是实现症状控制和减少病变生长的关键。橙色:功能增益;蓝色,用橙色圈出:增强信号。
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来源期刊
Angiogenesis
Angiogenesis PERIPHERAL VASCULAR DISEASE-
CiteScore
21.90
自引率
8.20%
发文量
37
审稿时长
6-12 weeks
期刊介绍: Angiogenesis, a renowned international journal, seeks to publish high-quality original articles and reviews on the cellular and molecular mechanisms governing angiogenesis in both normal and pathological conditions. By serving as a primary platform for swift communication within the field of angiogenesis research, this multidisciplinary journal showcases pioneering experimental studies utilizing molecular techniques, in vitro methods, animal models, and clinical investigations into angiogenic diseases. Furthermore, Angiogenesis sheds light on cutting-edge therapeutic strategies for promoting or inhibiting angiogenesis, while also highlighting fresh markers and techniques for disease diagnosis and prognosis.
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