Repression of rRNA gene transcription by endothelial SPEN deficiency normalizes tumor vasculature via nucleolar stress
Zi-Yan Yang, … , Tian Xiao, Hua Han
Zi-Yan Yang, … , Tian Xiao, Hua Han
Published August 22, 2023
Citation Information: J Clin Invest. 2023;133(20):e159860. https://doi.org/10.1172/JCI159860.
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Research Article Vascular biology

Repression of rRNA gene transcription by endothelial SPEN deficiency normalizes tumor vasculature via nucleolar stress

Abstract

Human cancers induce a chaotic, dysfunctional vasculature that promotes tumor growth and blunts most current therapies; however, the mechanisms underlying the induction of a dysfunctional vasculature have been unclear. Here, we show that split end (SPEN), a transcription repressor, coordinates rRNA synthesis in endothelial cells (ECs) and is required for physiological and tumor angiogenesis. SPEN deficiency attenuated EC proliferation and blunted retinal angiogenesis, which was attributed to p53 activation. Furthermore, SPEN knockdown activated p53 by upregulating noncoding promoter RNA (pRNA), which represses rRNA transcription and triggers p53-mediated nucleolar stress. In human cancer biopsies, a low endothelial SPEN level correlated with extended overall survival. In mice, endothelial SPEN deficiency compromised rRNA expression and repressed tumor growth and metastasis by normalizing tumor vessels, and this was abrogated by p53 haploinsufficiency. rRNA gene transcription is driven by RNA polymerase I (RNPI). We found that CX-5461, an RNPI inhibitor, recapitulated the effect of Spen ablation on tumor vessel normalization and combining CX-5461 with cisplatin substantially improved the efficacy of treating tumors in mice. Together, these results demonstrate that SPEN is required for angiogenesis by repressing pRNA to enable rRNA gene transcription and ribosomal biogenesis and that RNPI represents a target for tumor vessel normalization therapy of cancer.

Authors

Zi-Yan Yang, Xian-Chun Yan, Jia-Yu-Lin Zhang, Liang Liang, Chun-Chen Gao, Pei-Ran Zhang, Yuan Liu, Jia-Xing Sun, Bai Ruan, Juan-Li Duan, Ruo-Nan Wang, Xing-Xing Feng, Bo Che, Tian Xiao, Hua Han

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Figure 2

SPEN knockdown activates p53.

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SPEN knockdown activates p53. (A) Signature genes that are differentiall...
(A) Signature genes that are differentially expressed in HUVECs transduced with NC or SPENi lentivirus; the top 10 markedly changed entries were presented. (B and C) HUVECs were transduced with NC or SPENi lentivirus. The expression of p53 and its downstream genes was determined by (B) RT-qPCR (n = 4, except for n = 3 in p53) and (C) immunoblotting (n = 6, 5, and 3 for p53, p21, and GADD45A, respectively). β-Actin served as the loading control. (DF) HUVECs were transduced with NC or SPENi lentivirus and cultured with cycloheximide (CHX) as depicted. The p53 and MDM2 levels were assessed by immunoblotting at 0, 1, 2 and 3 hours after CHX addition (n = 5). β-Actin served as the loading control. The (E) p53 level and its (F) half-life were determined. The table in E shows the percentage of p53 level at different time points versus p53 level at 0 hours after CHX addition (**P < 0.01; ****P < 0.0001). (G) HUVECs were transduced with NC or SPENi lentivirus. Cell extracts were precipitated with anti-p53 and immunoblotted with anti-MDM2 (n = 3). Data represent mean ± SEM. Unpaired 2-tailed Student’s t test was used.