Micropeptide ASAP encoded by LINC00467 promotes colorectal cancer progression by directly modulating ATP synthase activity
Qiwei Ge, … , Shujie Chen, Liangjing Wang
Qiwei Ge, … , Shujie Chen, Liangjing Wang
Published September 30, 2021
Citation Information: J Clin Invest. 2021;131(22):e152911. https://doi.org/10.1172/JCI152911.
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Research Article Gastroenterology Oncology

Micropeptide ASAP encoded by LINC00467 promotes colorectal cancer progression by directly modulating ATP synthase activity

Abstract

Emerging evidence has shown that open reading frames inside long noncoding RNAs (lncRNAs) could encode micropeptides. However, their roles in cellular energy metabolism and tumor progression remain largely unknown. Here, we identified a 94 amino acid–length micropeptide encoded by lncRNA LINC00467 in colorectal cancer. We also characterized its conservation across higher mammals, localization to mitochondria, and the concerted local functions. This peptide enhanced the ATP synthase construction by interacting with the subunits α and γ (ATP5A and ATP5C), increased ATP synthase activity and mitochondrial oxygen consumption rate, and thereby promoted colorectal cancer cell proliferation. Hence, this micropeptide was termed ATP synthase–associated peptide (ASAP). Furthermore, loss of ASAP suppressed patient-derived xenograft growth with attenuated ATP synthase activity and mitochondrial ATP production. Clinically, high expression of ASAP and LINC00467 predicted poor prognosis of colorectal cancer patients. Taken together, our findings revealed a colorectal cancer–associated micropeptide as a vital player in mitochondrial metabolism and provided a therapeutic target for colorectal cancer.

Authors

Qiwei Ge, Dingjiacheng Jia, Dong Cen, Yadong Qi, Chengyu Shi, Junhong Li, Lingjie Sang, Luo-jia Yang, Jiamin He, Aifu Lin, Shujie Chen, Liangjing Wang

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Figure 3

ASAP promotes CRC cell proliferation in vitro and in vivo.

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ASAP promotes CRC cell proliferation in vitro and in vivo. (A–D) The CCK...
(AD) The CCK-8 assay was used to determine the proliferation rate of indicated cells. Data are presented as mean values ± SD. n = 3 biologically independent experiments. Two-way ANOVA analysis. ***P < 0.001. (E and F) Xenograft mouse model using EV control or ASAP, LINC00467-overexpressing (Lnc467), or Mut-LINC00467–overexpressing (Mut-Lnc467) HCT116 cells. In vivo generated tumors (E) and analyses of tumor growth and volume (F) are shown. Data are presented as mean ± SD from n = 5 mice per group. Two-way ANOVA. ***P < 0.001. (G and H) Xenograft mouse model using EV control or ASAP, LINC00467-overexpressing (Lnc467), or Mut-LINC00467–overexpressing (Mut-Lnc467) RKO cells. In vivo generated tumors (G) and analyses of tumor growth and volume (H) are shown. Data are presented as mean ± SD from n = 5 mice per group. Two-way ANOVA analysis. ***P < 0.001. (I and J) Xenograft mouse model using WT, ASAP-KO, LINC00467-restored (Lnc467), or Mut-LINC00467–restored (Mut-Lnc467) HCT116 cells. In vivo generated tumors (I) and analyses of tumor growth and volume (J) are shown. Data are presented as mean ± SD from n = 5 mice per group. Two-way ANOVA analysis. ***P < 0.001. (K and L) Xenograft mouse model using WT, ASAP-KO, LINC00467-restored (Lnc467), or Mut-LINC00467–restored (Mut-Lnc467) RKO cells. In vivo generated tumors (K) and analyses of tumor growth and volume (L) are shown. Data are presented as mean ± SD from n = 5 mice per group. Two-way ANOVA analysis. ***P < 0.001.