DISTRIBUTION OF PHOSPHATE-ACTIVATED GLUTAMINASE IN THE HUMAN CEREBRAL-CORTEX

被引：49

作者：

AKIYAMA, H ^{[1
]}

KANEKO, T ^{[1
]}

MIZUNO, N ^{[1
]}

MCGEER, PL ^{[1
]}

机构：

[1] KYOTO UNIV,DEPT ANAT,KYOTO 606,JAPAN

来源：

JOURNAL OF COMPARATIVE NEUROLOGY | 1990年 / 297卷 / 02期

关键词：

GABA; glutamate; non‐pyramidal neuron; pyramidal neuron;

D O I：

10.1002/cne.902970207

中图分类号：

Q189 [神经科学];

学科分类号：

071006 ;

摘要：

Phosphate‐activated glutaminase (PAG), which catalyses conversion of glutamine to glutamate, is a potential marker for glutamatergic, and possibly GABA, neurons in the central nervous system. A polyclonal antibody, raised in rabbits against rat brain PAG, was applied to postmortem human brain tissue to reveal the distribution of PAG in the cerebral cortex. PAG immunoreactivity was observed in pyramidal and non‐pyramidal neurons but not in glial cells. In the neocortex, large to medium‐sized pyramidal neurons in layers III and V were stained most intensely, while the majority of smaller pyramidal cells were labeled either lightly or moderately. Such modified pyramids as the giant Betz cells, the large pyramidal cells of Meynert, and the solitary cells of Ramón y Cajal were also stained intensely. Fusiform cells in layer VI showed moderate to intense labeling. A number of cortical non‐pyramidal neurons of various sizes stained moderately to intensely. These included large basket cells which were identified by their characteristic morphology and size in primary cortical areas. Pyramidal cells in the hippocampal formation as well as basket cells of the stratum oriens stained moderately to intensely. Since pyramidal cells are believed to be glutamatergic and large basket cells GABAergic, these results suggest that PAG plays a role in generating not only transmitter glutamate, but also GABA precursor glutamate. Copyright © 1990 Wiley‐Liss, Inc.

引用

页码：239 / 252

页数：14

共 59 条

[1] LOSS OF GLUTAMINASE-POSITIVE CORTICAL-NEURONS IN ALZHEIMERS-DISEASE
AKIYAMA, H
MCGEER, PL
ITAGAKI, S
MCGEER, EG
KANEKO, T
[J]. NEUROCHEMICAL RESEARCH, 1989, 14 (04) : 353 - 358
[2] IMMUNOCYTOCHEMICAL LOCALIZATION OF GLUTAMINASE-LIKE AND ASPARTATE AMINOTRANSFERASE-LIKE IMMUNOREACTIVITIES IN THE RAT AND GUINEA-PIG HIPPOCAMPUS
ALTSCHULER, RA
MONAGHAN, DT
HASER, WG
WENTHOLD, RJ
CURTHOYS, NP
COTMAN, CW
[J]. BRAIN RESEARCH, 1985, 330 (02) : 225 - 233
[3] GLIAL GLUTAMATE-DEHYDROGENASE - ULTRASTRUCTURAL-LOCALIZATION AND REGIONAL DISTRIBUTION IN RELATION TO THE MITOCHONDRIAL ENZYME, CYTOCHROME-OXIDASE
AOKI, C
MILNER, TA
BERGER, SB
SHEU, KFR
BLASS, JP
PICKEL, VM
[J]. JOURNAL OF NEUROSCIENCE RESEARCH, 1987, 18 (02) : 305 - 318
[4] AOKI C, 1987, J NEUROSCI, V7, P2214
[5] Bailey P, 1951, ISOCORTEX MAN
[6] D-[H-3]ASPARTATE RETROGRADE LABELING OF CALLOSAL AND ASSOCIATION NEURONS OF SOMATOSENSORY AREA-I AND AREA-II OF CATS
BARBARESI, P
FABRI, M
CONTI, F
MANZONI, T
[J]. JOURNAL OF COMPARATIVE NEUROLOGY, 1987, 263 (02) : 159 - 178
[7] BRAAK H, 1980, STUDIES BRAIN FUNCTI, V4
[8] BUTTERWORTH RF, 1983, GLUTAMINE GLUTAMATE, P595
[9] CORRELATION BETWEEN CYTOCHROME-OXIDASE STAINING AND THE UPTAKE AND LAMINAR DISTRIBUTION OF TRITIATED ASPARTATE, GLUTAMATE, GAMMA-AMINOBUTYRATE AND GLYCINE IN THE STRIATE CORTEX OF THE SQUIRREL-MONKEY
CARROLL, EW
WONGRILEY, M
[J]. NEUROSCIENCE, 1985, 15 (04) : 959 - 976
[10] CONTI F, 1988, J NEUROSCI, V8, P2948

← 1 2 3 4 5 6 →