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Targeting KIFC1 to disrupt centrosome clustering and trigger anaphase catastrophe in small-cell lung cancer
Natsuki Nakagawa, Minemichi Toda, Akiko Kunita, Masafumi Horie, Masakatsu Tokunaga, Hiroaki Ikushima, Mirei Ka, Takahiro Iida, Manabu Shigeoka, Yukinobu Ito, Takahiro Ando, Kousuke Watanabe, Yasunori Ota, Xi Liu, Ethan Dmitrovsky, Hidenori Kage, Masanori Kawakami
Natsuki Nakagawa, Minemichi Toda, Akiko Kunita, Masafumi Horie, Masakatsu Tokunaga, Hiroaki Ikushima, Mirei Ka, Takahiro Iida, Manabu Shigeoka, Yukinobu Ito, Takahiro Ando, Kousuke Watanabe, Yasunori Ota, Xi Liu, Ethan Dmitrovsky, Hidenori Kage, Masanori Kawakami
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Research Article Cell biology Oncology

Targeting KIFC1 to disrupt centrosome clustering and trigger anaphase catastrophe in small-cell lung cancer

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Abstract

Supernumerary centrosomes are a hallmark of cancer. To maintain viability, cancer cells cluster these centrosomes during mitosis, enabling bipolar division similar to that of normal cells. Disruption of this centrosome clustering leads to multipolar anaphase and apoptosis (anaphase catastrophe), which selectively eliminates cancer cells harboring supernumerary centrosomes. In this context, because the motor protein KIFC1 contributes to centrosome clustering, we investigated whether targeting of this mechanism through KIFC1 inhibition could be exploited in small-cell lung cancer (SCLC), an aggressive malignancy with limited treatment options and poor prognosis. Through in silico and in vitro analyses, as well as IHC of clinical samples, we found that KIFC1 is overexpressed and that centrosome amplification occurs more frequently in SCLC compared with normal tissues and other cancer types. Pharmacological and genetic inhibition of KIFC1 disrupted the clustering of supernumerary centrosomes, triggered multipolar mitosis, and exerted antineoplastic effects in SCLC cells, with minimal effects on noncancerous cells. These findings were validated and extended in vivo using SCLC xenograft models. Finally, cotargeting KIFC1 and the centrosome duplication regulator PLK4 further enhanced growth suppression in SCLC cells. Together, these results suggest that disrupting centrosome clustering and triggering anaphase catastrophe via KIFC1 inhibition may represent a promising therapeutic strategy for SCLC.

Authors

Natsuki Nakagawa, Minemichi Toda, Akiko Kunita, Masafumi Horie, Masakatsu Tokunaga, Hiroaki Ikushima, Mirei Ka, Takahiro Iida, Manabu Shigeoka, Yukinobu Ito, Takahiro Ando, Kousuke Watanabe, Yasunori Ota, Xi Liu, Ethan Dmitrovsky, Hidenori Kage, Masanori Kawakami

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Figure 7

Induction of anaphase catastrophe in SCLC cells following KIFC1 inhibition.

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Induction of anaphase catastrophe in SCLC cells following KIFC1 inhibiti...
(A) Representative immunofluorescence images of SCLC cells undergoing bipolar and multipolar anaphase. The blue signal is Hoechst 33342 staining (DNA), and the red signal is α-tubulin staining (spindles). Scale bars: 5 μm. Data are representative of 3 independent experiments. (B and C) Percentages of SCLC cells undergoing multipolar anaphase after AZ82 treatment (B) and after KIFC1 knockdown using siRNAs (C). Error bars represent standard deviation. P values were calculated using Dunnett’s method. *P < 0.05; **P < 0.01. (D) Representative immunofluorescence images showing 3 mitotic phenotypes in SCLC cells: bipolar cells with 2 centrosomes and normal bipolar spindles (left panels), pseudo-bipolar cells with supernumerary centrosomes clustered into 2 poles forming bipolar spindles (middle panels), and multipolar cells with unclustered supernumerary centrosomes forming multipolar spindles (right panels). The blue signal is Hoechst 33342 staining (DNA), the red signal is α-tubulin staining (spindles), and the green signal is pericentrin staining (centrosomes). Scale bars: 5 μm. Data are representative of 3 independent experiments. (E and F) Distribution of bipolar, pseudo-bipolar, and multipolar SCLC cells after AZ82 treatment (E) and after KIFC1 knockdown using siRNAs (F).

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