Subcortically and Callosally Projecting Neurons are Distinct Neuronal Pools in the Motor Cortex of the Reeler Mouse
スポンサーリンク
概要
- 論文の詳細を見る
Subcortically projecting neurons and callosally projecting ones are distinct neuronal pools in the cerebral cortex of the rodents. However, cortical efferent neurons are known to project multiple targets transiently by plural collateral axons. These plural axons are eliminated during prenatal and postnatal development. In the cerebral cortex of the Reelin-deficient mouse, reeler, which is caused by mutation of the reelin gene, cortical efferent neurons are ectopically distributed. However, it is still unknown whether cortical efferent neurons in the reeler mouse lose surplus collateral axons or maintain them during developmental periods. If surplus collaterals of malpositioned cortical neurons are not eliminated, neurons projecting subcortically may project their axons to the contralateral hemisphere. To test this plausible hypothesis, we made double injections of two fluorescent dyes, Fast Blue and Diamidino yellow dihydrochloride into two of three regions, i.e., upper cervical cord, ventral lateral thalamic nucleus, and contralateral motor cortex of the normal and reeler mice, to label corticospinal, corticothalamic and callosal commissure neurons in the motor cortex, retrogradely. No double labeled neurons were identified in the motor cortex of the normal and reeler mice, although the distribution patterns of these cortical efferent neurons were completely different between normal and reeler mice. These findings strongly suggest that collateral elimination of cortical efferent neurons during developing periods are not affected in this mutant mouse.
- 神戸大学の論文
- 2012-00-00
著者
-
Terashima Toshio
Division Of Anatomy And Developmental Neurobiology Department Of Neuroscience Kobe University Gradua
-
Katsuyama Yu
Division Of Anatomy And Developmental Neurobiology Department Of Physiology And Cell Biology Kobe Un
-
KIKKAWA Satoshi
Division of Anatomy and Developmental Neurobiology, Kobe University Graduate School of Medicine
-
Kikkawa Satoshi
Division Of Anatomy And Developmental Neurobiology Kobe University Graduate School Of Medicine
-
Yamamoto Tatsuro
Division Of Developmental Neurobiology Department Of Physiology And Cell Biology Kobe University Gra
-
Imai Hideaki
Division Of Anatomy And Neurobiology Department Of Physiology And Cell Biology Kobe University Graduate School Of Medicine
-
Terashima Toshio
Division of Anatomy and Developmental Neurobiology, Kobe University Graduate School of Medicine
-
Yamamoto Tatsuro
Division of Anatomy and Developmental Neurobiology, Kobe University Graduate School of Medicine
-
Katsuyama Yu
Division of Anatomy and Developmental Neurobiology, Kobe University Graduate School of Medicine
-
Imai Hideaki
Division of Anatomy and Developmental Neurobiology, Kobe University Graduate School of Medicine
関連論文
- Nerve communication between the glossopharyngeal nerve, external carotid plexus and the superficial cervical ansa : Human autopsy case
- 統合失調症とアルツハイマー病との関連性 : リーリン・シグナル伝達系
- Dispersion of the neurons expressing layer specific markers in the reeler brain
- Cortical Layer V Neurons in the Auditory and Visual Cortices of Normal, reeler, and yotari Mice
- Anterograde labeling of the corticospinal tract in jimpy mutant mice by DiI injection into the motor cortex
- Intramuscular nerve distribution pattern of the oblique and transverse heads of the adductor hallucis muscles in the human foot
- PKH26 is an excellent retrograde and anterograde fluorescent tracer characterized by a small injection site and strong fluorescence emission
- Histological study in the brain of the reelin/Dab1-compound mutant mouse
- Developmental anatomy of reeler mutant mouse
- Macroscopic and histological observations on the human sternoclavicular joint disc
- Dynamic changes in the gene expression of zebrafish Reelin receptors during embryogenesis and hatching period
- Subcortically and Callosally Projecting Neurons are Distinct Neuronal Pools in the Motor Cortex of the Reeler Mouse
- Function of strawberry notch Family Genes in the Zebrafish Brain Development