Your search keyword '"Ze-Hui Zheng"' showing total 7 results

1. Yeast in addition to pollen enhances the reproduction of the predatory mite Euseius nicholsi by increasing the target of rapamycin gene expression

Author

Meng-Ru Jin, Tian-Rong Xin, Ze-Hui Zheng, Cong Zhang, Xin-Yu Huang, Zhen-Zhen Li, Yi-Meng Liu, Jing Wang, Zhi-Wen Zou, and Bin Xia

Subjects

Insect Science, Agronomy and Crop Science

Published

2023

2. Target-specific differences in somatodendritic morphology of layer V pyramidal neurons in rat motor cortex

Author

Wen-Jun Gao and Ze-Hui Zheng

Subjects

Male, Population, Thalamus, Pyramidal Tracts, In Vitro Techniques, Biology, Synaptic Transmission, Rats, Sprague-Dawley, chemistry.chemical_compound, medicine, Animals, education, Fluorescent Dyes, Lucifer yellow, education.field_of_study, Pyramidal tracts, Pyramidal Cells, General Neuroscience, Motor Cortex, Dendrites, Isoquinolines, Retrograde tracing, Corpus Striatum, Rats, medicine.anatomical_structure, nervous system, chemistry, Cerebral cortex, Soma, Neuroscience, Motor cortex

Abstract

Dendritic geometry has been shown to be a critical determinant of information processing and neuronal computation. However, it is not known whether cortical projection neurons that target different subcortical nuclei have distinct dendritic morphologies. In this study, fast blue retrograde tracing in combination with intracellular Lucifer yellow injection and diaminobenzidine (DAB) photoconversion in fixed slices was used to study the morphological features of corticospinal, corticostriatal, and corticothalamic neurons in layer V of rat motor cortex. Marked differences in the distribution of soma, somal size, and dendritic profiles were found among the three groups of pyramidal neurons. Corticospinal neurons were large, were located in deep layer V, and had the most expansive dendritic fields. The apical dendrites of corticospinal pyramidal neurons were thick, spiny, and branched. In contrast, nearly all corticostriatal neurons were small cells located in superficial layer V. Their apical dendritic shafts were significantly more slender, though spiny like those of corticospinal neurons. Corticothalamic neurons, which were located in superficial layer V and in layer VI, had small or medium-sized soma, slender apical dendritic shafts, and dendrites that were largely spine free. This study indicates that, in layer V of rat motor cortex, each population of projection neurons has a unique somatodendritic morphology and suggests that distinct modes of cortical information processing are operative in corticospinal, corticostriatal, and corticothalamic neurons.

Published

2004

3. Distribution of synapses on an intracellularly labeled small pyramidal neuron in the cat motor cortex

Author

Xiao-Bo Liu, Ming-Chu Xi, Ze-Hui Zheng, and Chinn-Ping Wu

Subjects

Embryology, Pyramidal Tracts, Biology, law.invention, Synapse, Basal (phylogenetics), law, medicine, Animals, Horseradish Peroxidase, Neurons, Motor Cortex, Cell Biology, Anatomy, Microscopy, Electron, medicine.anatomical_structure, Cerebral cortex, Synapses, Cats, Biophysics, Ultrastructure, Soma, Neuron, Electron microscope, Developmental Biology, Motor cortex

Abstract

The morphological characteristics and distribution of synapses on a small pyramidal neuron in layer III of the cat motor cortex have been studied by combining intracellular HRP staining and electron microscopic examination. The stained neuron showed spiny apical and basal dendritic profiles under the light microscope, and exhibited the morphological features of a pyramidal neuron. Ultrastructural analysis indicated that about 80% of the presynaptic terminals formed asymmetrical synapses with spines of distal apical and basal dendrites. On proximal apical dendrites, 64% of the synapses were found to make contact with spines, and 16.7% of the synapses were of symmetrical type and formed with dendritic shafts. Two types of terminal could be identified on the soma; they were alternately located and established symmetrical and asymmetrical synaptic contacts respectively. Possible functional implications are discussed.

Published

1991

4. Distribution of synapses on fast and slow pyramidal tract neurons in the cat. An electron microscopic study

Author

Ming-Chu Xi, Chien-Ping Wu, Xiao-Bo Liu, and Ze-Hui Zheng

Subjects

Pyramidal Tracts, Biology, Functional Laterality, law.invention, Synapse, law, medicine, Animals, Molecular Biology, Electron microscopic, Neurons, Pyramidal tracts, General Neuroscience, Motor Cortex, Dendrites, Antidromic, Microscopy, Electron, medicine.anatomical_structure, Cerebral cortex, Synapses, Cats, Soma, Neurology (clinical), Electron microscope, Neuroscience, Developmental Biology, Motor cortex

Abstract

Distributions of synapses on various portions of fast and slow pyramidal tract neurons (PTNs) in cat motor cortex were studied with electron microscopy. PTNs were identified by their antidromic invasion following stimulation of the medullary pyramid and were classified into fast and slow PTNs according to conduction velocities of their axons. Two fast and two slow PTNs were intracellularly labeled and, by systematic sampling, electron micrographs from various portions of these neurons were examined to compare the distributions of different types of synapses. It was found that most synapses formed on apical and basal dendrites of fast PTNs were with the dendritic shafts. In slow PTNs, while synapses on apical dendrites were mostly axospinous, about 70% of the sampled synapses on basal dendrites of slow PTNs were established with the dendritic shafts. Virtually all synapses on apical dendrites of slow PTNs belonged to asymmetrical type and most of the synapses sampled from basal dendrites of fast PTNs were also asymmetrical. On the other hand, about 29% of the synapses found on apical dendrites of fast PTNs were symmetrical and a trend was observed for this type of synapses to increase their number with increasing proximity to the cell body. Over 28% of the synapses on basal dendrites of slow PTNs were also symmetrical and seemed to be mainly distributed in layer VI. All synapses formed on the soma were symmetrical both for the fast and slow PTNs.

Published

1991

5. Thalamic projection to motor area and area 3a of the cat cerebral cortex

Author

Chien-Ping Wu, Ze-Hui Zheng, and Ming-Chu Xi

Subjects

Neurons, Brain Mapping, Motor area, Microinjections, General Neuroscience, Motor Cortex, medicine.anatomical_structure, Thalamus, Cerebral cortex, Cats, medicine, Animals, Neurology (clinical), Projection (set theory), Psychology, Molecular Biology, Fast blue, Nucleus, Neuroscience, Fluorescent Dyes, Developmental Biology, Motor cortex

Abstract

The distributions of thalamic neurons projecting to the motor cortex and cortical area 3a were studied in cat by means of the retrograde double-labeling technique using Nuclear Yellow (NY) and Fast Blue (FB) as tracers. Following injection of NY and FB into the motor cortex and area 3a respectively, the NY-labeled neurons were found to be mainly located in ventrolateral (VL) nucleus and FB-labeled neurons in ventro-posterolateral nucleus (VPL). However, these two kinds of neurons were intermingled with each other in the border area between VL and VPL. A small number of neurons were double-labeled by both NY and FB. They were also distributed in the border area. Some of them could often be found in centromedian and parafascicular nuclei.

Published

1986

6. Direct synaptic linkage of ventrolateral nucleus of thalamus terminal with cat fast pyramidal tract neuron

Author

Xiaobo Liu, Chien-Ping Wu, Ming-Chu Xi, and Ze-Hui Zheng

Subjects

Time Factors, Thalamus, Pyramidal Tracts, Synaptic Transmission, Horseradish peroxidase, law.invention, Synapse, law, Neural Pathways, medicine, Animals, Molecular Biology, Neurons, Pyramidal tracts, biology, General Neuroscience, food and beverages, Microscopy, Electron, medicine.anatomical_structure, Terminal (electronics), Thalamic Nuclei, Synapses, Cats, biology.protein, Neurology (clinical), Neuron, Electron microscope, Neuroscience, Developmental Biology, Motor cortex

Abstract

An electron microscopic study on the synaptic connections between neurons of ventrolateral nucleus of thalamus (VL) and pyramidal tract neurons (PTNs) in cat motor cortex was conducted by means of the anterograde degenerating procedure coupled with horseradish peroxidase (HRP) intracellular staining. Following VL lesions, a large majority of the degenerating terminals were found to terminate on dentritic spines and a few on the dendritic shaft. An asymmetric type synapse formed by a VL degenerating terminal and the dendritic shaft of a branch of apical dentrite of a labeled fast pyramidal tract neurons was demonstrated.

Published

1986

7. The cerebellar corticovestibular projection in the cat as studied with retrograde transport of horseradish peroxidase

Author

Ze-hui Zheng, Espen Dietrichs, and Fred Walberg

Subjects

Embryology, biology, Chemistry, Cell Biology, Flocculus, Anatomy, Vestibular Nuclei, Horseradish peroxidase, Cerebellar Cortex, Purkinje Cells, nervous system, Projection (mathematics), Vestibular nuclei, Ventral paraflocculus, Neural Pathways, otorhinolaryngologic diseases, Axoplasmic transport, biology.protein, Cats, Animals, Neuroscience, Horseradish Peroxidase, Developmental Biology

Abstract

The cerebellar corticovestibular projection in the cat was studied by means of retrograde transport of HRP. After injections confined to the vestibular nuclei retrogradely labelled Purkinje cells were found ipsilaterally in vermal lobules I through X, crus I, the ventral paraflocculus and flocculus. The neurons projecting to the vestibular nuclei are located in all parts of the cerebellar folia (bottom, side and top). Most of the vestibular projecting Purkinje cells are located within a sagittal band (corresponding to Voogd's B zone) in the lateral vermis. In some of our cats the width of this band exceeds 1 mm in lobule I, 800 microns in lobule II and 1.5 mm in lobule V. However, the sagittal band is not sharply demarcated, and some retrogradely labelled Purkinje cells were present almost in the midline while others were located more than 4 mm lateral to this. The findings are discussed with special emphasis on the cerebellar sagittal zonal arrangement and related to previous studies on the cerebellar corticovestibular projection.

Published

1983