TY - JOUR
T1 - Cerebral angiogenesis ameliorates pathological disorders in Nemo-deficient mice with small-vessel disease
AU - Jiang, Yun
AU - Müller, Kristin
AU - Khan, Mahtab A.
AU - Assmann, Julian C.
AU - Lampe, Josephine
AU - Kilau, Knut
AU - Richter, Marius
AU - Kleint, Maximilian
AU - Ridder, Dirk A.
AU - Hübner, Norbert
AU - Schmidt-Supprian, Marc
AU - Wenzel, Jan
AU - Schwaninger, Markus
N1 - Publisher Copyright:
© The Author(s) 2020.
PY - 2021/2
Y1 - 2021/2
N2 - Cerebral small-vessel diseases (SVDs) often follow a progressive course. Little is known about the function of angiogenesis, which potentially induces regression of SVDs. Here, we investigated angiogenesis in a mouse model of incontinentia pigmenti (IP), a genetic disease comprising features of SVD. IP is caused by inactivating mutations of Nemo, the essential component of NF-κB signaling. When deleting Nemo in the majority of brain endothelial cells (NemobeKO mice), the transcriptional profile of vessels indicated cell proliferation. Brain endothelial cells expressed Ki67 and showed signs of DNA synthesis. In addition to cell proliferation, we observed sprouting and intussusceptive angiogenesis in NemobeKO mice. Angiogenesis occurred in all segments of the vasculature and in proximity to vessel rarefaction and tissue hypoxia. Apparently, NEMO was required for productive angiogenesis because endothelial cells that had escaped Nemo inactivation showed a higher proliferation rate than Nemo-deficient cells. Therefore, newborn endothelial cells were particularly vulnerable to ongoing recombination. When we interfered with productive angiogenesis by inducing ongoing ablation of Nemo, mice did not recover from IP manifestations but rather showed severe functional deficits. In summary, the data demonstrate that angiogenesis is present in this model of SVD and suggest that it may counterbalance the loss of vessels.
AB - Cerebral small-vessel diseases (SVDs) often follow a progressive course. Little is known about the function of angiogenesis, which potentially induces regression of SVDs. Here, we investigated angiogenesis in a mouse model of incontinentia pigmenti (IP), a genetic disease comprising features of SVD. IP is caused by inactivating mutations of Nemo, the essential component of NF-κB signaling. When deleting Nemo in the majority of brain endothelial cells (NemobeKO mice), the transcriptional profile of vessels indicated cell proliferation. Brain endothelial cells expressed Ki67 and showed signs of DNA synthesis. In addition to cell proliferation, we observed sprouting and intussusceptive angiogenesis in NemobeKO mice. Angiogenesis occurred in all segments of the vasculature and in proximity to vessel rarefaction and tissue hypoxia. Apparently, NEMO was required for productive angiogenesis because endothelial cells that had escaped Nemo inactivation showed a higher proliferation rate than Nemo-deficient cells. Therefore, newborn endothelial cells were particularly vulnerable to ongoing recombination. When we interfered with productive angiogenesis by inducing ongoing ablation of Nemo, mice did not recover from IP manifestations but rather showed severe functional deficits. In summary, the data demonstrate that angiogenesis is present in this model of SVD and suggest that it may counterbalance the loss of vessels.
KW - Angiogenesis
KW - NF-κB
KW - endothelial cell
KW - incontinentia pigmenti
KW - small vessel disease
UR - http://www.scopus.com/inward/record.url?scp=85081982442&partnerID=8YFLogxK
U2 - 10.1177/0271678X20910522
DO - 10.1177/0271678X20910522
M3 - Article
C2 - 32151223
AN - SCOPUS:85081982442
SN - 0271-678X
VL - 41
SP - 219
EP - 235
JO - Journal of Cerebral Blood Flow and Metabolism
JF - Journal of Cerebral Blood Flow and Metabolism
IS - 2
ER -