MICRENCEPHALY REDUCES THE PHOSPHORYLATION OF THE PKC SUBSTRATE B-50/GAP43 IN RAT CORTEX AND HIPPOCAMPUS

被引：22

作者：

DILUCA, M

CIMINO, M

DEGRAAN, PNE

OESTREICHER, AB

GISPEN, WH

CATTABENI, F

机构：

[1] UNIV URBINO,INST PHARMACOL & PHARMACOGNOSY,I-61029 URBINO,ITALY

[2] STATE UNIV UTRECHT,INST MOLEC BIOL,DIV MOLEC NEUROBIOL,UTRECHT,NETHERLANDS

[3] STATE UNIV UTRECHT,RUDOLF MAGNUS INST,UTRECHT,NETHERLANDS

来源：

BRAIN RESEARCH | 1991年 / 538卷 / 01期

关键词：

MICRENCEPHALY; METHYLAZOXYMETHANOL; PROTEIN PHOSPHORYLATION; PROTEIN KINASE C; B-50/GAP43; CORTEX; HIPPOCAMPUS; RAT;

D O I：

10.1016/0006-8993(91)90381-5

中图分类号：

Q189 [神经科学];

学科分类号：

071006 ;

摘要：

The administration of the antimitotic agent methylazoxymethanol (MAM) to rats at day 15 of gestation results in a consistent loss of intrinsic neurons primarily in cortex and hippocampus. These animals when adult, show a cognitive impairment, if tested in specific behavioural tasks. B-50/GAP43 is a neuronal phosphoprotein, specific substrate for protein kinase C (PKC) and involved in the development and plasticity of synaptic connections. Since B-50/GAP43 has been implicated in functional modulation of synapses and in the molecular mechanism underlying cognitive processes, we studied the phosphorylation of B-50 in cortex and hippocampus of control and MAM-treated rats. Here we report that B-50 in MAM-treated rats shows a marked reduction in the phosphate incorporation in the areas affected by the prenatal treatment. In situ hybridization studies demonstrate that the mRNA levels for B-50 are not altered in MAM-treated rats and that the relative amount of the protein, as revealed by Western blot analysis, is also not affected in microencephalic rats. These results suggest that microencephalic animals might represent a useful experimental model to study biochemical correlates of cognitive impairment and synaptic plasticity.

引用

页码：95 / 101

页数：7

共 49 条

[1] PROTEIN KINASE-C PHOSPHORYLATES A 47-MR PROTEIN (F1) DIRECTLY RELATED TO SYNAPTIC PLASTICITY
AKERS, RF
ROUTTENBERG, A
[J]. BRAIN RESEARCH, 1985, 334 (01) : 147 - 151
[2] TRANSLOCATION OF PROTEIN-KINASE-C ACTIVITY MAY MEDIATE HIPPOCAMPAL LONG-TERM POTENTIATION
AKERS, RF
LOVINGER, DM
COLLEY, PA
LINDEN, DJ
ROUTTENBERG, A
[J]. SCIENCE, 1986, 231 (4738) : 587 - 589
[3] PHOSPHORYLATION OF SYNAPTIC PROTEINS IN CHICK FOREBRAIN - CHANGES WITH DEVELOPMENT AND PASSIVE-AVOIDANCE TRAINING
ALI, SM
BULLOCK, S
ROSE, SPR
[J]. JOURNAL OF NEUROCHEMISTRY, 1988, 50 (05) : 1579 - 1587
[4] ALOJO VJ, 1983, J NEUROCHEM, V41, P649
[5] LOSS OF INTRINSIC STRIATAL NEURONS AFTER METHYLAZOXYMETHANOL ACETATE TREATMENT IN PREGNANT RATS
BALDUINI, W
ABBRACCHIO, MP
LOMBARDELLI, G
CATTABENI, F
[J]. DEVELOPMENTAL BRAIN RESEARCH, 1984, 15 (01): : 133 - 136
[6] MICROENCEPHALIC RATS AS A MODEL FOR COGNITIVE DISORDERS
BALDUINI, W
CIMINO, M
LOMBARDELLI, G
ABBRACCHIO, MP
PERUZZI, G
CECCHINI, T
GAZZANELLI, GC
CATTABENI, F
[J]. CLINICAL NEUROPHARMACOLOGY, 1986, 9 : S8 - S18
[7] CLASSICAL-CONDITIONING INDUCES LONG-TERM TRANSLOCATION OF PROTEIN KINASE-C IN RABBIT HIPPOCAMPAL CA1 CELLS
BANK, B
DEWEER, A
KUZIRIAN, AM
RASMUSSEN, H
ALKON, DL
[J]. PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA, 1988, 85 (06) : 1988 - 1992
[8] A MEMBRANE PHOSPHOPROTEIN ASSOCIATED WITH NEURAL DEVELOPMENT, AXONAL REGENERATION, PHOSPHOLIPID-METABOLISM, AND SYNAPTIC PLASTICITY
BENOWITZ, LI
ROUTTENBERG, A
[J]. TRENDS IN NEUROSCIENCES, 1987, 10 (12) : 527 - 532
[9] BRADFORD MM, 1976, ANAL BIOCHEM, V72, P248, DOI 10.1016/0003-2697(76)90527-3
[10] CIMLER BM, 1987, J BIOL CHEM, V262, P12158

← 1 2 3 4 5 →