Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches

Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches

Previously, studying the development, especially of corticospinal neurons, it was concluded that the main compensatory mechanism after unilateral brain injury in rat at the neonatal stage was due in part to non-lesioned ipsilateral corticospinal neurons that escaped selection by axonal elimination o...

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Main Authors: Akira Yoshikawa, Tomoya Nakamachi, Junko Shibato, Randeep Rakwal, Seiji Shioda
Format: Article
Language:English
Published: MDPI AG 2014-12-01
Series:International Journal of Molecular Sciences
Subjects:
neonatal
adult
brain
motor functional recovery
DNA microarray
8 × 60 K
transcriptome profiling
gene inventory
Online Access:http://www.mdpi.com/1422-0067/15/12/22492
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spelling doaj-8b0b7fe8f4be478a9409e27e2f0e62d32020-11-24T21:06:54ZengMDPI AGInternational Journal of Molecular Sciences1422-00672014-12-011512224922251710.3390/ijms151222492ijms151222492Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray ApproachesAkira Yoshikawa0Tomoya Nakamachi1Junko Shibato2Randeep Rakwal3Seiji Shioda4Department of Anatomy, Showa University School of Medicine, 1-5-8 Hatanodai, Shinagawa, Tokyo 142-8555, JapanDepartment of Anatomy, Showa University School of Medicine, 1-5-8 Hatanodai, Shinagawa, Tokyo 142-8555, JapanDepartment of Anatomy, Showa University School of Medicine, 1-5-8 Hatanodai, Shinagawa, Tokyo 142-8555, JapanDepartment of Anatomy, Showa University School of Medicine, 1-5-8 Hatanodai, Shinagawa, Tokyo 142-8555, JapanDepartment of Anatomy, Showa University School of Medicine, 1-5-8 Hatanodai, Shinagawa, Tokyo 142-8555, JapanPreviously, studying the development, especially of corticospinal neurons, it was concluded that the main compensatory mechanism after unilateral brain injury in rat at the neonatal stage was due in part to non-lesioned ipsilateral corticospinal neurons that escaped selection by axonal elimination or neuronal apoptosis. However, previous results suggesting compensatory mechanism in neonate brain were not correlated with high functional recovery. Therefore, what is the difference among neonate and adult in the context of functional recovery and potential mechanism(s) therein? Here, we utilized a brain unilateral decortication mouse model and compared motor functional recovery mechanism post-neonatal brain hemisuction (NBH) with adult brain hemisuction (ABH). Three analyses were performed: (1) Quantitative behavioral analysis of forelimb movements using ladder walking test; (2) neuroanatomical retrograde tracing analysis of unlesioned side corticospinal neurons; and (3) differential global gene expressions profiling in unlesioned-side neocortex (rostral from bregma) in NBH and ABH on a 8 × 60 K mouse whole genome Agilent DNA chip. Behavioral data confirmed higher recovery ability in NBH over ABH is related to non-lesional frontal neocortex including rostral caudal forelimb area. A first inventory of differentially expressed genes genome-wide in the NBH and ABH mouse model is provided as a resource for the scientific community.http://www.mdpi.com/1422-0067/15/12/22492neonataladultbrainmotor functional recoveryDNA microarray8 × 60 Ktranscriptome profilinggene inventory
collection DOAJ
language English
format Article
sources DOAJ
author Akira Yoshikawa
Tomoya Nakamachi
Junko Shibato
Randeep Rakwal
Seiji Shioda
spellingShingle Akira Yoshikawa
Tomoya Nakamachi
Junko Shibato
Randeep Rakwal
Seiji Shioda
Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
International Journal of Molecular Sciences
neonatal
adult
brain
motor functional recovery
DNA microarray
8 × 60 K
transcriptome profiling
gene inventory
author_facet Akira Yoshikawa
Tomoya Nakamachi
Junko Shibato
Randeep Rakwal
Seiji Shioda
author_sort Akira Yoshikawa
title Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
title_short Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
title_full Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
title_fullStr Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
title_full_unstemmed Comprehensive Analysis of Neonatal versus Adult Unilateral Decortication in a Mouse Model Using Behavioral, Neuroanatomical, and DNA Microarray Approaches
title_sort comprehensive analysis of neonatal versus adult unilateral decortication in a mouse model using behavioral, neuroanatomical, and dna microarray approaches
publisher MDPI AG
series International Journal of Molecular Sciences
issn 1422-0067
publishDate 2014-12-01
description Previously, studying the development, especially of corticospinal neurons, it was concluded that the main compensatory mechanism after unilateral brain injury in rat at the neonatal stage was due in part to non-lesioned ipsilateral corticospinal neurons that escaped selection by axonal elimination or neuronal apoptosis. However, previous results suggesting compensatory mechanism in neonate brain were not correlated with high functional recovery. Therefore, what is the difference among neonate and adult in the context of functional recovery and potential mechanism(s) therein? Here, we utilized a brain unilateral decortication mouse model and compared motor functional recovery mechanism post-neonatal brain hemisuction (NBH) with adult brain hemisuction (ABH). Three analyses were performed: (1) Quantitative behavioral analysis of forelimb movements using ladder walking test; (2) neuroanatomical retrograde tracing analysis of unlesioned side corticospinal neurons; and (3) differential global gene expressions profiling in unlesioned-side neocortex (rostral from bregma) in NBH and ABH on a 8 × 60 K mouse whole genome Agilent DNA chip. Behavioral data confirmed higher recovery ability in NBH over ABH is related to non-lesional frontal neocortex including rostral caudal forelimb area. A first inventory of differentially expressed genes genome-wide in the NBH and ABH mouse model is provided as a resource for the scientific community.
topic neonatal
adult
brain
motor functional recovery
DNA microarray
8 × 60 K
transcriptome profiling
gene inventory
url http://www.mdpi.com/1422-0067/15/12/22492
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AT tomoyanakamachi comprehensiveanalysisofneonatalversusadultunilateraldecorticationinamousemodelusingbehavioralneuroanatomicalanddnamicroarrayapproaches
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