Association of impaired neuronal migration with cognitive deficits in extremely preterm infants
Ken-ichiro Kubo, Kimiko Deguchi, Taku Nagai, Yukiko Ito, Keitaro Yoshida, Toshihiro Endo, Seico Benner, Wei Shan, Ayako Kitazawa, Michihiko Aramaki, Kazuhiro Ishii, Minkyung Shin, Yuki Matsunaga, Kanehiro Hayashi, Masaki Kakeyama, Chiharu Tohyama, Kenji F. Tanaka, Kohichi Tanaka, Sachio Takashima, Masahiro Nakayama, Masayuki Itoh, Yukio Hirata, Barbara Antalffy, Dawna D. Armstrong, Kiyofumi Yamada, Ken Inoue, Kazunori Nakajima
Ken-ichiro Kubo, Kimiko Deguchi, Taku Nagai, Yukiko Ito, Keitaro Yoshida, Toshihiro Endo, Seico Benner, Wei Shan, Ayako Kitazawa, Michihiko Aramaki, Kazuhiro Ishii, Minkyung Shin, Yuki Matsunaga, Kanehiro Hayashi, Masaki Kakeyama, Chiharu Tohyama, Kenji F. Tanaka, Kohichi Tanaka, Sachio Takashima, Masahiro Nakayama, Masayuki Itoh, Yukio Hirata, Barbara Antalffy, Dawna D. Armstrong, Kiyofumi Yamada, Ken Inoue, Kazunori Nakajima
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Research Article Development Neuroscience

Association of impaired neuronal migration with cognitive deficits in extremely preterm infants

Abstract

Many extremely preterm infants (born before 28 gestational weeks [GWs]) develop cognitive impairment in later life, although the underlying pathogenesis is not yet completely understood. Our examinations of the developing human neocortex confirmed that neuronal migration continues beyond 23 GWs, the gestational week at which extremely preterm infants have live births. We observed larger numbers of ectopic neurons in the white matter of the neocortex in human extremely preterm infants with brain injury and hypothesized that altered neuronal migration may be associated with cognitive impairment in later life. To confirm whether preterm brain injury affects neuronal migration, we produced brain damage in mouse embryos by occluding the maternal uterine arteries. The mice showed delayed neuronal migration, ectopic neurons in the white matter, altered neuronal alignment, and abnormal corticocortical axonal wiring. Similar to human extremely preterm infants with brain injury, the surviving mice exhibited cognitive deficits. Activation of the affected medial prefrontal cortices of the surviving mice improved working memory deficits, indicating that decreased neuronal activity caused the cognitive deficits. These findings suggest that altered neuronal migration altered by brain injury might contribute to the subsequent development of cognitive impairment in extremely preterm infants.

Authors

Ken-ichiro Kubo, Kimiko Deguchi, Taku Nagai, Yukiko Ito, Keitaro Yoshida, Toshihiro Endo, Seico Benner, Wei Shan, Ayako Kitazawa, Michihiko Aramaki, Kazuhiro Ishii, Minkyung Shin, Yuki Matsunaga, Kanehiro Hayashi, Masaki Kakeyama, Chiharu Tohyama, Kenji F. Tanaka, Kohichi Tanaka, Sachio Takashima, Masahiro Nakayama, Masayuki Itoh, Yukio Hirata, Barbara Antalffy, Dawna D. Armstrong, Kiyofumi Yamada, Ken Inoue, Kazunori Nakajima

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Figure 5

Effect of brain injury on neurodevelopment in the mouse neocortex.

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Effect of brain injury on neurodevelopment in the mouse neocortex. (A) S...
(A) Schematic representation of the procedure for producing the mouse model of brain injury. (B) Representative photograph of maternal uterine arteries occluded with 4 disposable vascular clips. (C) Brains of control embryos (left) and occluded embryos (middle and right) 12 hours after occlusion. Sections were immunostained with anti-PH3 antibody (counterstained with DAPI). SVZ, subventricular zone; VZ, ventricular zone. Scale bar: 100 μm. (D) The numbers of PH3-positive cells in the VZ and SVZ are shown (control: n = 18, moderate: n = 19, severe: n = 6). A Kruskal-Wallis test followed by Dunnett’s post-hoc test was used. **P < 0.01. (E) After transfection of GFP expression plasmid at E15.0, a sham operation (Control) or maternal uterine artery occlusion (Occluded) was performed at E16.5. Brains were analyzed at P1 (counterstained with DAPI [blue]). MZ, marginal zone; CP, cortical plate. Scale bar: 100 μm. (F) Cell distribution was evaluated by bin analysis. Data obtained in 5 control brains and 6 occluded brains (mean ± SEM) are shown. **P < 0.01, ***P < 0.001, repeated-measures ANOVA followed by Bonferroni post-hoc test. (G) Relative migration distances (%) from the ventricle. Average relative migration distances in 5 control brains and 6 occluded brains are shown. **P < 0.01, Student’s t test. (D and G) Each point represents an individual mouse. Box-and-whisker plots were used to graphically represent the median (line within box), upper and lower quartiles (bounds of box), and maximum and minimum values (top and bottom bars).