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Free amino acid level determinations in normal and schizophrenic brain
Pmg. Neum-Psychophormocol. L+Biol. Psychiot. Printed in Great Britain. AIL rights reserved
027~584tYgQ $0.00 + SO Copyright @ 1989 Pergamon Press plc
lQg9. Vol. 13, pp. 119-126
FREE AMINO ACID LEVEL DETERMINATIONS AND SCHIZOPHRENIC BRAIN FATMA Z.KUTAYl,
$AKlRE
Ege University,
POGDN*,
NURAN i.HARtRt*,
IN NORMAL
GSNDL PEKER* and SERMET
S hool of Medicine, Departments of 'Biochemistry 3 Physiology, Bornova, fzmir, Turkey
(Final form August
ERLACfNl and
1988)
Abstract I(utay Faba Z.,$akire P8gDn, Nuran 1. Hariri, GiinDl Peker and Sermet Erlacin : Free amino acid 7eve1 determinations in normal and schizophrenic brain. Prog. Neuro-Psychopharmacol. and Biol. Psychiat. 1989, 13: jig-126
1. Some disturbances in brain amino acids are reported with regard to pathological changes in schizophrenia: a reduction in GABA content and a reduced activity at some glutamatergic synapses. 2. Comparison of post-mortem brain tissue from control subjects and schizophrenic patients can provide evidence for amino acid alterations in disease. 3. The present study was undertaken to measure free amino acid concentrations in 20 brain regions obtained at autopsy, from normal persons and schizophrenics. Amino acids were extracted, esterified and separated by gas chromatography. 4. The distribution and levels of amino acids in normal persons is in accordance with similar values reported in human post-mortem brain samples by other investigators. 5. The differences in amino acids found in schizophrenic brain samples support the view of disturbed neurotransmission especially with regard to GABAergic and glutamatergic systems in schizophrenia and suggest the possible involvement of other amiro acids as well.
: Amino acid levels, post-mortem
Keywords
human brain, schizophrenia.
Abbreviations: alanine (Ala), asparagine (As NH ), aspartate (Asp), ethylene glycol adipate (EGA), gamma-aminobutyric acid (GABA P , Glutamate (Glu), glutamic acid decarboxylase (GAD), glutamine (GluNH ), glycine (Gly), isoleucine (ILe), leucine (Leu), lysine (Lys), methionine (Met), 8rnithine (Orn), phenylalanine (Phe), proline(Pro), valine (Val).
Introduction Amino acids have started of synaptic
function
neurotransmitters
putative
of dopamine.
types of schizophrenia interaction tic terminal tissue effects
or candidate.
may be a result of a defect
the effects
as neurotransmitters partially
or as neuromodulators
in an effort
to find the "missing"
in brain. Today, while some are proven to be neurotransmitters,
still are considered zophrenia
to gain recognition
during the past decades,
GABA ergic deficiency
receptors
the dopaminergic
may be a characteristic
system
release
observed
others in schi-
systems modulating finding
in some
from the nerve ending
and
, some of the GABA is taken back to the presynap-
while the rest is catabolized butyrate
hyperactivity
in one or more neurotransmission
(Perry et al., 1979). Following
with postsynaptic
to gamma hydroxy
Dopaminergic
enzymatically
in the nerve terminals
(McGeer et al., 1979; McGeer (Cash et al., 1981).
119
and McGeer,
The co-existance
or glial
1981) which
of GABA with
120
F. 2. Kutay etal.
serotonin
was observed
transmission
systems
in some neurons
since human brain is inaccessible
levels during a disease
Regarding
following
to CSF or plasma
to reflect
the putative
information
the relative
on absolute
differences
between
pathologyof schizophrinia,
neurotransmitter
in their brain distribution,
free amino acids in 20 regions
methionine,
the majority
et al., 1985;
group.
the role of amino acids in the etiological
and schizophrenic
(Bjerkensted
amino acid levels may not provide
the first place, but considering and the variability
disorders,
for direct amino acid level determinations,
life, but they may be assumed
and a control
the two neuro-
appear likely in many neuropsychiatric
in the field were restricted
Enna et al., 1977). Post-mortem
between
et al., 1981).
(Nanopoulos
Even though amino acid alterations
of the studies
and there is an interaction
patients:
phenylalanine,
alanine,
of post-mortem
valine,
aspartate,
the authors
glycine,
glutamate,
GABA has
roles of other amino acids determined
the levels of the
human brains in normal subjects
isoleucine,
ornithine,
leucine,
proline,
GABA,
lysine.
Methods Human Post-mortem
Brain Specimens
The brains of schizophrenic normal
persons without
University
Hospital)
patients
who died in Manisa,
any neuropsychiatric
were obtained
disease
at autopsy
(20 regions),
1 ml of 2.5 mM norleucine
was added as the internal
were studied;
time between
(Dept. of Forensic
and examined
The brains were dissected
weighed,
renics whose mean age was 40 and 3 male,
State Psychiatric
standard.
1 female normal
Medicine,
to exclude
put in saturated
Hospital,
and
Ege
any gross pathology.
picric acid (l/10)
and
5 Male, 2 female schizoph-
persons whose mean age was 31
death and autopsy was 65 (48-83) hours for the schizophrrnics
and 48 (20-56) hours for the normal persons. Preparation
of Tissue
for Gas Chromatoqraphic
Tissue was homogenized
at 1400 rpm using a glass-teflon
at 3000 x g for 15 minutes. x 7 cm) containing was collected lyophilized.
The supernatant
7N NH40H through
The lyophilizate
ration
homogenizer
through
under nitrogen
(0.9 cm
The amino acid fraction
in O.IN HCI and transferred
lined screw caps. Esterification
3N HCI, and acetylation
and centrifuged
glass columns
the column with a flow rate of 3 ml/min.
was dissolved
rycle.. The amino acid trifluoro dryness
was eluted
Dowex 50 W x 12 and washed with d.d. water.
by passing
tubes with teflon n.Butanol
Separation
in 5 minutes
acetyl n-butyl
occurred
in 15 minutes
at 100°C with
at 15O'C with trifluoroacetic derivatives
and stored at -2O'C in chloroform
obtained,
and
to acetylation
acid anhyd-
were brought
until gas chromatographic
to sepa-
(Kutay et al., 1983).
Amino Acid Analysis Pye-Unicam
104 gas chromatograph
in 2 nn~!x 180 cm glass columns program
between
60-21O'C.
was used for separation.
containing
The amino acids were separated
0.65 % EGA chromosorb
W.NAW using a 6'C/min,
The areas under the amino acid peaks were calculated
using an
Amino acids in normal and scbizopbrenic brain
121
integrator (Spectra Physics Minigrator) and the actual amino acid levels were determined (Kutay et al., 1983). Results The following amino acids were separated chromatographically : alanine, valine, glycine, isoleucine, leucine, proline, GABA, methionine, phenylalanine, aspartate, glutamate, ornithine, lysine.Since glutamine and asparagine are converted to their acid forms during esterification, they were evaluated together with glutamate and aspartate. The peak of the internal standard, norleucine, was between leucine and proline. The free amino acid distribution in 20 regions of normal, post-mortem human brain is seen in Table 1. The amino acids glycine, GABA, aspartate and glutamate reveal a local distribution pattern which is in accordance with their physiological functions. There is also a striking difference in the distribution of the amino acids alanine, leucine, proline, methionine, phenylalanine,ornithine and lysine. The differences mentioned were also observed when each case was evaluated separately. The free amino acid distribution in post-mortem schizophrenic brain specimens is seen in Table 2. The differences between the two groups are summarized in Table 3. Discussion The majority of amino acids are higher in autopsied brain specimens compared to biopsies (Perry et al., 1971a and b). The continuing activity of some synthetic enzymes, changes in ATP levels and deamination reactions account for these changes which occur during the first few minutes after death (Minard and Mushahwar, 1966; Perry et al.,
1971a; Peterson
and McKean, 1969). Since post-mortem conditions are identical in both groups included in our study, we believe that our results reflect the relative differences which will provide important cues with regard to the possible pathological changes observed in schizophrenia.. Distribution of Amino Acids in Normal Brain In our study, the normal amino acid levels and their distribution is in accordance with the values reported by other investigators (Bachelard, 1981; McGeer et al., 1979; Perry et al., 1971a; Okumuraet al.,
1960) (Table 1.). There is no direct measurement of free
amino acid levels in autopsied schizophrenic brain regions, however there are some studies reporting changes in amino acid levels and related transport systems in the CSF and plasma of schizophrenic patients (Okumura et al., 1960). Changes in Amino Acids in Schizophrenic Brain In our study, in schizophrenics,we found high levels of neutral amino acids in many brain regions (Table 2) compared to normals, which can be attributed to a defect in the L-transport system. High levels of phenylalanine in the thalamus and some cortical areas of schizophrenics (Tables 2 and 3) may imply a defect in the conversion of phenylalanine to tyrosine which will subsequently effect catecholamine metabolism as suggested by
0.50
1.81
1.09
2.87
Dorsal
Subs. nigra 3.05 2.14
3.03 2.98
1.25
2.46
Medulla spinalis
Cerebellar
Asp + AspNH2,
**
Glu + GluNH2
wet weight of tissue
pmol/g.
*
cortex
4.91
6.49 1.65
5.39
3.36
2.17
2.57
2.19
Red n.
2.61
4.34
1.17
4.69
Globus pallidus
2.66 2.91
3.01
Putamen
2.92
1.31 1.42
3.11
Caudate n. (body)
2.59
1.60
2.72
2.31
3.21
1.22
2.54
Caudate n. (head)
Extrapyramidal areas
1.20
2.61
Ventral 1.75
Hippocampus
2.79
1.19
Thalamus
1.51
2.20
2.63
3.39
0.80
1.60
2.48
Amygdala
Limbic cortex
Corpus callosum
1.60
1.53
2.95 1.63
0.84
2.11
Inf.temp.gyr.
Sup.temp.gyr.
1.76
1.96
2.91
0.91
1.71
(fis.calc.)
Occip.
2.99
2.65
3.25
1.19
3.54
(assoc)
Occip.
3.01
2.06
3.38
3.65
2.63
2.21
1.10
gyr.
gyr. 0.93
Postcent.
2.41
Precent.
2.50
1.39
1.81
Leu
0.63
Gly
1.53
Val
2.48 1.94 3.71 0.38
0.93 0.65 1.85 0.90
3.94 4.56 4.92 3.06
9.12 0.87 3.13
1.62 1.32
1.36 1.56
0.50
1.01 0.53
0.95
1.04
0.69
0.67
1.59
3.57
1.30
2.63
3.76
1.35
1.11
2.46
3.78
1.27
3.41
2.80
1.38
2.84
1.40 0.83
1.04
2.45
GABA
0.51 0.31 1.13 0.55
0.51 0.59 0.50 0.40
1.73 0.85 0.48
1.33 1.06
0.66
0.56
0.89
0.57 0.57
3.20
5.41
12.04
3.30
4.61
3.25
4.16 0.51
3.32
0.55
3.26
3.08
2.42
4.06
2.00
4.76
2.83
3.93
4.87
3.64
3.70
2.90
** Asp
0.72
0.88
0.56
0.61
0.46
0.41
0.28
0.50
0.88
1.28
0.62
0.66
0.62
0.91
0.86
0.59
0.61
0.44
Phe
(Normal)*
0.36
Met
of Human Brain
0.68
Pro
Regions
1
1.48
0.56
0.40
0.56
0.63
0.52
0.38
0.89
0.45
0.46
0.82
0.50
0.53
0.31
ILe
in Different
Cerebral hemispheres Frontal pole
Ala
Free Amino Acids
Table
0.29 -
9.12 13.09 6.49
0.47 0.29
6.78 9.56
0.75
-
15.5
0.34
7.61
9.68
0.58
0.31
6.56
0.24
8.06
0.32
3.76
10.8
0.14
9.08
13.53
0.25 0.08
7.28
0.32
9.81 8.69
0.15 0.10
7.25 8.83
0.09
Orn
10.72
** Glu
1.05
1.57
3.49
1.45
2.17
1.51
1.48
1.93
1.03
0.32
1.06
2.27
0.42
1.03
0.60
0.52
1.23
0.74
1.15
0.59
Lys
2.86
2.87
Ventral
Dorsal
0.90
1.38
Putamen
Globus pallidus
0.99
Cerebellar
cortex
2.62
Medulla spinalis
Red n.
1.52
0.148
Caudate n. (head)
Caudate n. (body)
areas
1.91
Extrapyramidal
1.09
Hippocampus
1.64
Amygdala
Limbic cortex
Corpus callosum
1.86
Sup.temp.gyr.
2.01
2.45
(fis talc.)
Occip.
1.92
Inf.temp.gyr.
(assoc)
Occip.
1.45
1.56
gyr.
gyr.
Precent.
Postcent.
1.56
Cerebral hemispheres Frontal pole
Ala
1.25
1.65
2.00
1.17
1.42
1.31
1.22
1.09
1.20
1.19
0.80
0.50
1.53
0.84
0.91
1.19
0.93
1.10
0.63
Val
2.38
3.09
3.12
4.58
2.07
0.68
1.02
2.89
4.29
2.01
1.75
1.95
2.33
1.95
2.51
1.58
2.07
1.71
2.12
Gly
Free Amino Acids
2.46
2.62
1.65
1.87
1.04
1.65
1.69
1.99
2.04
1.74
1.31
1.35
1.72
1.62
2.48
1.71
1.45
1.69
1.72
Leu
0.48
0.90
0.90
3.80
0.59
0.37
0.44
0.72
1.06
3.89
0.76
0.76
0.42
0.46
0.45
0.54
0.81
0.44
1.36
1.16
2.32
1.20
0.70
0.87
0.59
0.69
0.66
0.87
0.80
0.82
0.84
1.14
1.14
0.80
0.80
1.01
Pro
Regions
0.55
ILe
in Different
Table 2
1.69
0.85
4.67
5.14
4.88
2.17
2.64
1.06
1.72
1.36
1.33
0.49
1.94
1.63
2.24
1.30
1.96
1.53
1.45
GABA
0.39
0.72
0.47
0.54
0.28
0.50
-
-
-
0.51
0.39
0.21
0.43
0.64
0.31
0.52
0.34
0.45
Met
0.56
0.76
0.88
0.71
0.68
0.73
0.98
1.01
0.49
0.57
0.42
0.53
0.95
0.65
0.69
0.48
0.55
0.64
Phe
2.26
1.65
4.73
2.18
1.35
3.02
2.65
3.71
1.80
2.75
1.73
1.68
1.98
3.27
2.75
2.28
2.41
2.49
Asp
of Human Brain (Schizophrenic)
13.41
7.49
20.05
21.68
18.32
17.0
18.72
15.39
10.14
14.27
7.63
14.92
14.85
16.66
6.66
12.48
11.72
17.81
Glu
0.32
0.45
1.03
0.64
0.40
0.29
0.39
0.029
0.089
0.21
0.37
0.23
0.13
0.21
0.20
0.29
0.17
0.18
0.21
Orn
1.53
1.13
2.20
0.96
1.20
0.93
1.19
0.26
0.51
0.85
0.72
0.84
0.85
1.27
0.86
0.92
0.34
1.09
Lys
124
F. Z. Kutay et al.
c c -4 -
4
-
I
P -
.
- 4
-4
Amino acids in normal and schizophrenic
brain
125
Potkin (Potkin et al., 1983). Table 3 shows a fall in GABA levels in most of the regions in schizophrenic brains; this finding supports other investigators'opinions regarding a deficiency in GABA ergic activity in the etiological pathology of schizophrenia (Bracha and Kleinman, 1986; Ko et al., 1985; Perry et al., 1979). In schizophrenics,glutamate levels show a negative correlation with GABA in our study (Table 3), which may imply a decline in GAD activity in schizophrenia;a possible neurotoxic effect of glutamate may also be contributing to the symptomatic manifestions of schizophrenia. Evaluation of our results also reveal changes of some amino acids without known neuroactive functions, in some regions of schizophrenic brains (Tables 2 and 3). Another finding is a change in the distribution of some amino acids in schizophrenia (Tables 1 and 2). Even though these changes reveal possible roles of amino acids in the schizophrenic syndrome, we don't have enough informationyet to give explanations for all the differences observed. Conclusion The comparison of free amino acid levels in normal and schizophrenic post-mortem brain samples show that there is disturbed neurotransmissionespecially with regard to GABA ergic and glutamatergic systems in schizophrenic brains. Our data also suggest the possible involvement of other amino acids. Further research involving post-mortem studies will elucidate the roles of amino acids in health and disease. Acknowledgement This study was supported by the Ege University Research Foundation Grant No:025/84. References BACHELARD,H.S. Biochemistry of centrally active amino acids. (1981) In: Amino Acid Neurotransmitters,F.V.De Feudis and P.Mandel (Eds.) pp: 475-497, Raven Press, NewYork. BJERKENSTED,L., EDMAN,G., HAGENFELDT,L., SEDVALL,G., WIESEL,F.A. (1985) Plasma amino acids in relation to cerebrospinal fluid monoamine metabolites in schizophrenic patients andhealthy controls. Brit.J.psychiat.147, 276-282. BRACHA,H.S. and KLEIMAN,J.E. (1986) Post-mortem neurochemistry in schizophrenia. Psychiat. Clin.Nerth America. 9 (1): 133-141. CASH,C.D.,RUMIGNY,J.E.,MANDEL.P.,MAITRE,M.(1981) Enzymology of the alternative reductive pathway of GABA catabolism leading to the biosynthesis of gama hydroxy butyrate. pp: 527-535, Raven Press, NewYork. ,.CNNA,S.J., WOOD,J.H., SNYDER,S.H. (1977) Gamma-amino butyric acid (GABA) in human cerebrospinal fluid. Radioreceptor assay.J.Neurochem.-28: 1120-1124. KO,G.N., KORPI,E.R.,FREED,M.J.,ZALCHMAN,S.J., BtGELOW,L.B., 1985. Effect of valproic acid on behavior and plasma amino acid contentrations in chronic schizophrenic patients. Biol. Psychiatry -20: 209-215. KUTAY.F., 0NAT.T.. ERLACIN,S. (1983) Plasma, kas ve karacigerde serbest amino asidlerin gaz-likid kromatografisi ile analizi. E.D.T.F. dergisi, 22(4): 1007-16. MC GEER,P.L., ECCLES,J.C., MC GEER,E.G. (1979) Molecular Neurobiology of the Manzaalian Brain. pp: 199-230, Plenum Press, NewYork and London.
126
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MC GEER,P.L. and MC GEER, E.G. (1981) Amino acid neurotrasmitters. In: Basic Neuro-, chemistry,Siegel, G.J., Albers, R.W., Agranoff, B.W., Katzman, R. (Eds.) pp: 233-253, Little, Brown and company, Boston. MINARD,F.N. and MUSHAHVAR,L.K. (1966) Synthesis of gana butyric acid from a pool of glutamic acid in brain after decapitation. Life Sciences, 5: 1409-1413. NANOPOULOS,D., MAITRE,M., BELIN,M.F., AGUERO,M., PUJOL,J.F., GAMRANI,H., CALAS,A. (1981) Autoradiographic and immune cytochemical evidence for the existence of GABA-ergic neurons in the nucleus raphe dorsalis-possible existence of neurons containing 5HT lutamate decarboxylase. In: Amino Acid Neurotransmitters, F.V. De Feudis and P.Mantel 9 Eds.) pp: 519-525, Raven Press, NewYork. OKUMURA,N., OTSUKI,S., KAMEYAMA,A. J.Biochem. 47(3): 315-320.
(1960) Studies
on free amino acids
in human brain.
PERRY,T.L., BERRY.K., HANSEN,S., DIAMOND,S., MOK,C. (1971a) Regional distribution amino acids in human brain obtained at autopsy. J.Neurochem. -18: 513-519.
of
PERRY,T.L.,HANSEN,S., BERRY,K., MOK,C., LESK,D. (1971b) Free amino acids and related compounds in biopsies of human brain. J.Neurochem. -18: 521-528. PERRY,T.L. KISH,S.J., BUCHANON,J. (1979) Garena amino butyric of schizophrenic patients. Lancet, I: 237-239.
acid deficiency
in brain
PETERSON,N.A. and MC KEAN,C.M. (1969) The effects of individual amino acids on the corporation of labelled amino acids into proteins by brain homogenates. J.Neurochem. 16: 1211-1217. POTKIN,S.G., CANNON-SPOOR,H.E., De LISI,L.E., NECKERS,L.M., WYATT,R.J. (1983) Plasma phenylalanine, tyrosine and tryptophan in schizophrenia. Arch-Gen. Psychiatry. 40: 749-752. Inquiries
and reprint
requests
Dr.Fatma Z.KUTAY Assoc.Prof. of Biochemistry Ege University, Medical School Department of Biochemistry Bornova,fzmir TURKEY
should
be addressed
to:
027~584tYgQ $0.00 + SO Copyright @ 1989 Pergamon Press plc
lQg9. Vol. 13, pp. 119-126
FREE AMINO ACID LEVEL DETERMINATIONS AND SCHIZOPHRENIC BRAIN FATMA Z.KUTAYl,
$AKlRE
Ege University,
POGDN*,
NURAN i.HARtRt*,
IN NORMAL
GSNDL PEKER* and SERMET
S hool of Medicine, Departments of 'Biochemistry 3 Physiology, Bornova, fzmir, Turkey
(Final form August
ERLACfNl and
1988)
Abstract I(utay Faba Z.,$akire P8gDn, Nuran 1. Hariri, GiinDl Peker and Sermet Erlacin : Free amino acid 7eve1 determinations in normal and schizophrenic brain. Prog. Neuro-Psychopharmacol. and Biol. Psychiat. 1989, 13: jig-126
1. Some disturbances in brain amino acids are reported with regard to pathological changes in schizophrenia: a reduction in GABA content and a reduced activity at some glutamatergic synapses. 2. Comparison of post-mortem brain tissue from control subjects and schizophrenic patients can provide evidence for amino acid alterations in disease. 3. The present study was undertaken to measure free amino acid concentrations in 20 brain regions obtained at autopsy, from normal persons and schizophrenics. Amino acids were extracted, esterified and separated by gas chromatography. 4. The distribution and levels of amino acids in normal persons is in accordance with similar values reported in human post-mortem brain samples by other investigators. 5. The differences in amino acids found in schizophrenic brain samples support the view of disturbed neurotransmission especially with regard to GABAergic and glutamatergic systems in schizophrenia and suggest the possible involvement of other amiro acids as well.
: Amino acid levels, post-mortem
Keywords
human brain, schizophrenia.
Abbreviations: alanine (Ala), asparagine (As NH ), aspartate (Asp), ethylene glycol adipate (EGA), gamma-aminobutyric acid (GABA P , Glutamate (Glu), glutamic acid decarboxylase (GAD), glutamine (GluNH ), glycine (Gly), isoleucine (ILe), leucine (Leu), lysine (Lys), methionine (Met), 8rnithine (Orn), phenylalanine (Phe), proline(Pro), valine (Val).
Introduction Amino acids have started of synaptic
function
neurotransmitters
putative
of dopamine.
types of schizophrenia interaction tic terminal tissue effects
or candidate.
may be a result of a defect
the effects
as neurotransmitters partially
or as neuromodulators
in an effort
to find the "missing"
in brain. Today, while some are proven to be neurotransmitters,
still are considered zophrenia
to gain recognition
during the past decades,
GABA ergic deficiency
receptors
the dopaminergic
may be a characteristic
system
release
observed
others in schi-
systems modulating finding
in some
from the nerve ending
and
, some of the GABA is taken back to the presynap-
while the rest is catabolized butyrate
hyperactivity
in one or more neurotransmission
(Perry et al., 1979). Following
with postsynaptic
to gamma hydroxy
Dopaminergic
enzymatically
in the nerve terminals
(McGeer et al., 1979; McGeer (Cash et al., 1981).
119
and McGeer,
The co-existance
or glial
1981) which
of GABA with
120
F. 2. Kutay etal.
serotonin
was observed
transmission
systems
in some neurons
since human brain is inaccessible
levels during a disease
Regarding
following
to CSF or plasma
to reflect
the putative
information
the relative
on absolute
differences
between
pathologyof schizophrinia,
neurotransmitter
in their brain distribution,
free amino acids in 20 regions
methionine,
the majority
et al., 1985;
group.
the role of amino acids in the etiological
and schizophrenic
(Bjerkensted
amino acid levels may not provide
the first place, but considering and the variability
disorders,
for direct amino acid level determinations,
life, but they may be assumed
and a control
the two neuro-
appear likely in many neuropsychiatric
in the field were restricted
Enna et al., 1977). Post-mortem
between
et al., 1981).
(Nanopoulos
Even though amino acid alterations
of the studies
and there is an interaction
patients:
phenylalanine,
alanine,
of post-mortem
valine,
aspartate,
the authors
glycine,
glutamate,
GABA has
roles of other amino acids determined
the levels of the
human brains in normal subjects
isoleucine,
ornithine,
leucine,
proline,
GABA,
lysine.
Methods Human Post-mortem
Brain Specimens
The brains of schizophrenic normal
persons without
University
Hospital)
patients
who died in Manisa,
any neuropsychiatric
were obtained
disease
at autopsy
(20 regions),
1 ml of 2.5 mM norleucine
was added as the internal
were studied;
time between
(Dept. of Forensic
and examined
The brains were dissected
weighed,
renics whose mean age was 40 and 3 male,
State Psychiatric
standard.
1 female normal
Medicine,
to exclude
put in saturated
Hospital,
and
Ege
any gross pathology.
picric acid (l/10)
and
5 Male, 2 female schizoph-
persons whose mean age was 31
death and autopsy was 65 (48-83) hours for the schizophrrnics
and 48 (20-56) hours for the normal persons. Preparation
of Tissue
for Gas Chromatoqraphic
Tissue was homogenized
at 1400 rpm using a glass-teflon
at 3000 x g for 15 minutes. x 7 cm) containing was collected lyophilized.
The supernatant
7N NH40H through
The lyophilizate
ration
homogenizer
through
under nitrogen
(0.9 cm
The amino acid fraction
in O.IN HCI and transferred
lined screw caps. Esterification
3N HCI, and acetylation
and centrifuged
glass columns
the column with a flow rate of 3 ml/min.
was dissolved
rycle.. The amino acid trifluoro dryness
was eluted
Dowex 50 W x 12 and washed with d.d. water.
by passing
tubes with teflon n.Butanol
Separation
in 5 minutes
acetyl n-butyl
occurred
in 15 minutes
at 100°C with
at 15O'C with trifluoroacetic derivatives
and stored at -2O'C in chloroform
obtained,
and
to acetylation
acid anhyd-
were brought
until gas chromatographic
to sepa-
(Kutay et al., 1983).
Amino Acid Analysis Pye-Unicam
104 gas chromatograph
in 2 nn~!x 180 cm glass columns program
between
60-21O'C.
was used for separation.
containing
The amino acids were separated
0.65 % EGA chromosorb
W.NAW using a 6'C/min,
The areas under the amino acid peaks were calculated
using an
Amino acids in normal and scbizopbrenic brain
121
integrator (Spectra Physics Minigrator) and the actual amino acid levels were determined (Kutay et al., 1983). Results The following amino acids were separated chromatographically : alanine, valine, glycine, isoleucine, leucine, proline, GABA, methionine, phenylalanine, aspartate, glutamate, ornithine, lysine.Since glutamine and asparagine are converted to their acid forms during esterification, they were evaluated together with glutamate and aspartate. The peak of the internal standard, norleucine, was between leucine and proline. The free amino acid distribution in 20 regions of normal, post-mortem human brain is seen in Table 1. The amino acids glycine, GABA, aspartate and glutamate reveal a local distribution pattern which is in accordance with their physiological functions. There is also a striking difference in the distribution of the amino acids alanine, leucine, proline, methionine, phenylalanine,ornithine and lysine. The differences mentioned were also observed when each case was evaluated separately. The free amino acid distribution in post-mortem schizophrenic brain specimens is seen in Table 2. The differences between the two groups are summarized in Table 3. Discussion The majority of amino acids are higher in autopsied brain specimens compared to biopsies (Perry et al., 1971a and b). The continuing activity of some synthetic enzymes, changes in ATP levels and deamination reactions account for these changes which occur during the first few minutes after death (Minard and Mushahwar, 1966; Perry et al.,
1971a; Peterson
and McKean, 1969). Since post-mortem conditions are identical in both groups included in our study, we believe that our results reflect the relative differences which will provide important cues with regard to the possible pathological changes observed in schizophrenia.. Distribution of Amino Acids in Normal Brain In our study, the normal amino acid levels and their distribution is in accordance with the values reported by other investigators (Bachelard, 1981; McGeer et al., 1979; Perry et al., 1971a; Okumuraet al.,
1960) (Table 1.). There is no direct measurement of free
amino acid levels in autopsied schizophrenic brain regions, however there are some studies reporting changes in amino acid levels and related transport systems in the CSF and plasma of schizophrenic patients (Okumura et al., 1960). Changes in Amino Acids in Schizophrenic Brain In our study, in schizophrenics,we found high levels of neutral amino acids in many brain regions (Table 2) compared to normals, which can be attributed to a defect in the L-transport system. High levels of phenylalanine in the thalamus and some cortical areas of schizophrenics (Tables 2 and 3) may imply a defect in the conversion of phenylalanine to tyrosine which will subsequently effect catecholamine metabolism as suggested by
0.50
1.81
1.09
2.87
Dorsal
Subs. nigra 3.05 2.14
3.03 2.98
1.25
2.46
Medulla spinalis
Cerebellar
Asp + AspNH2,
**
Glu + GluNH2
wet weight of tissue
pmol/g.
*
cortex
4.91
6.49 1.65
5.39
3.36
2.17
2.57
2.19
Red n.
2.61
4.34
1.17
4.69
Globus pallidus
2.66 2.91
3.01
Putamen
2.92
1.31 1.42
3.11
Caudate n. (body)
2.59
1.60
2.72
2.31
3.21
1.22
2.54
Caudate n. (head)
Extrapyramidal areas
1.20
2.61
Ventral 1.75
Hippocampus
2.79
1.19
Thalamus
1.51
2.20
2.63
3.39
0.80
1.60
2.48
Amygdala
Limbic cortex
Corpus callosum
1.60
1.53
2.95 1.63
0.84
2.11
Inf.temp.gyr.
Sup.temp.gyr.
1.76
1.96
2.91
0.91
1.71
(fis.calc.)
Occip.
2.99
2.65
3.25
1.19
3.54
(assoc)
Occip.
3.01
2.06
3.38
3.65
2.63
2.21
1.10
gyr.
gyr. 0.93
Postcent.
2.41
Precent.
2.50
1.39
1.81
Leu
0.63
Gly
1.53
Val
2.48 1.94 3.71 0.38
0.93 0.65 1.85 0.90
3.94 4.56 4.92 3.06
9.12 0.87 3.13
1.62 1.32
1.36 1.56
0.50
1.01 0.53
0.95
1.04
0.69
0.67
1.59
3.57
1.30
2.63
3.76
1.35
1.11
2.46
3.78
1.27
3.41
2.80
1.38
2.84
1.40 0.83
1.04
2.45
GABA
0.51 0.31 1.13 0.55
0.51 0.59 0.50 0.40
1.73 0.85 0.48
1.33 1.06
0.66
0.56
0.89
0.57 0.57
3.20
5.41
12.04
3.30
4.61
3.25
4.16 0.51
3.32
0.55
3.26
3.08
2.42
4.06
2.00
4.76
2.83
3.93
4.87
3.64
3.70
2.90
** Asp
0.72
0.88
0.56
0.61
0.46
0.41
0.28
0.50
0.88
1.28
0.62
0.66
0.62
0.91
0.86
0.59
0.61
0.44
Phe
(Normal)*
0.36
Met
of Human Brain
0.68
Pro
Regions
1
1.48
0.56
0.40
0.56
0.63
0.52
0.38
0.89
0.45
0.46
0.82
0.50
0.53
0.31
ILe
in Different
Cerebral hemispheres Frontal pole
Ala
Free Amino Acids
Table
0.29 -
9.12 13.09 6.49
0.47 0.29
6.78 9.56
0.75
-
15.5
0.34
7.61
9.68
0.58
0.31
6.56
0.24
8.06
0.32
3.76
10.8
0.14
9.08
13.53
0.25 0.08
7.28
0.32
9.81 8.69
0.15 0.10
7.25 8.83
0.09
Orn
10.72
** Glu
1.05
1.57
3.49
1.45
2.17
1.51
1.48
1.93
1.03
0.32
1.06
2.27
0.42
1.03
0.60
0.52
1.23
0.74
1.15
0.59
Lys
2.86
2.87
Ventral
Dorsal
0.90
1.38
Putamen
Globus pallidus
0.99
Cerebellar
cortex
2.62
Medulla spinalis
Red n.
1.52
0.148
Caudate n. (head)
Caudate n. (body)
areas
1.91
Extrapyramidal
1.09
Hippocampus
1.64
Amygdala
Limbic cortex
Corpus callosum
1.86
Sup.temp.gyr.
2.01
2.45
(fis talc.)
Occip.
1.92
Inf.temp.gyr.
(assoc)
Occip.
1.45
1.56
gyr.
gyr.
Precent.
Postcent.
1.56
Cerebral hemispheres Frontal pole
Ala
1.25
1.65
2.00
1.17
1.42
1.31
1.22
1.09
1.20
1.19
0.80
0.50
1.53
0.84
0.91
1.19
0.93
1.10
0.63
Val
2.38
3.09
3.12
4.58
2.07
0.68
1.02
2.89
4.29
2.01
1.75
1.95
2.33
1.95
2.51
1.58
2.07
1.71
2.12
Gly
Free Amino Acids
2.46
2.62
1.65
1.87
1.04
1.65
1.69
1.99
2.04
1.74
1.31
1.35
1.72
1.62
2.48
1.71
1.45
1.69
1.72
Leu
0.48
0.90
0.90
3.80
0.59
0.37
0.44
0.72
1.06
3.89
0.76
0.76
0.42
0.46
0.45
0.54
0.81
0.44
1.36
1.16
2.32
1.20
0.70
0.87
0.59
0.69
0.66
0.87
0.80
0.82
0.84
1.14
1.14
0.80
0.80
1.01
Pro
Regions
0.55
ILe
in Different
Table 2
1.69
0.85
4.67
5.14
4.88
2.17
2.64
1.06
1.72
1.36
1.33
0.49
1.94
1.63
2.24
1.30
1.96
1.53
1.45
GABA
0.39
0.72
0.47
0.54
0.28
0.50
-
-
-
0.51
0.39
0.21
0.43
0.64
0.31
0.52
0.34
0.45
Met
0.56
0.76
0.88
0.71
0.68
0.73
0.98
1.01
0.49
0.57
0.42
0.53
0.95
0.65
0.69
0.48
0.55
0.64
Phe
2.26
1.65
4.73
2.18
1.35
3.02
2.65
3.71
1.80
2.75
1.73
1.68
1.98
3.27
2.75
2.28
2.41
2.49
Asp
of Human Brain (Schizophrenic)
13.41
7.49
20.05
21.68
18.32
17.0
18.72
15.39
10.14
14.27
7.63
14.92
14.85
16.66
6.66
12.48
11.72
17.81
Glu
0.32
0.45
1.03
0.64
0.40
0.29
0.39
0.029
0.089
0.21
0.37
0.23
0.13
0.21
0.20
0.29
0.17
0.18
0.21
Orn
1.53
1.13
2.20
0.96
1.20
0.93
1.19
0.26
0.51
0.85
0.72
0.84
0.85
1.27
0.86
0.92
0.34
1.09
Lys
124
F. Z. Kutay et al.
c c -4 -
4
-
I
P -
.
- 4
-4
Amino acids in normal and schizophrenic
brain
125
Potkin (Potkin et al., 1983). Table 3 shows a fall in GABA levels in most of the regions in schizophrenic brains; this finding supports other investigators'opinions regarding a deficiency in GABA ergic activity in the etiological pathology of schizophrenia (Bracha and Kleinman, 1986; Ko et al., 1985; Perry et al., 1979). In schizophrenics,glutamate levels show a negative correlation with GABA in our study (Table 3), which may imply a decline in GAD activity in schizophrenia;a possible neurotoxic effect of glutamate may also be contributing to the symptomatic manifestions of schizophrenia. Evaluation of our results also reveal changes of some amino acids without known neuroactive functions, in some regions of schizophrenic brains (Tables 2 and 3). Another finding is a change in the distribution of some amino acids in schizophrenia (Tables 1 and 2). Even though these changes reveal possible roles of amino acids in the schizophrenic syndrome, we don't have enough informationyet to give explanations for all the differences observed. Conclusion The comparison of free amino acid levels in normal and schizophrenic post-mortem brain samples show that there is disturbed neurotransmissionespecially with regard to GABA ergic and glutamatergic systems in schizophrenic brains. Our data also suggest the possible involvement of other amino acids. Further research involving post-mortem studies will elucidate the roles of amino acids in health and disease. Acknowledgement This study was supported by the Ege University Research Foundation Grant No:025/84. References BACHELARD,H.S. Biochemistry of centrally active amino acids. (1981) In: Amino Acid Neurotransmitters,F.V.De Feudis and P.Mandel (Eds.) pp: 475-497, Raven Press, NewYork. BJERKENSTED,L., EDMAN,G., HAGENFELDT,L., SEDVALL,G., WIESEL,F.A. (1985) Plasma amino acids in relation to cerebrospinal fluid monoamine metabolites in schizophrenic patients andhealthy controls. Brit.J.psychiat.147, 276-282. BRACHA,H.S. and KLEIMAN,J.E. (1986) Post-mortem neurochemistry in schizophrenia. Psychiat. Clin.Nerth America. 9 (1): 133-141. CASH,C.D.,RUMIGNY,J.E.,MANDEL.P.,MAITRE,M.(1981) Enzymology of the alternative reductive pathway of GABA catabolism leading to the biosynthesis of gama hydroxy butyrate. pp: 527-535, Raven Press, NewYork. ,.CNNA,S.J., WOOD,J.H., SNYDER,S.H. (1977) Gamma-amino butyric acid (GABA) in human cerebrospinal fluid. Radioreceptor assay.J.Neurochem.-28: 1120-1124. KO,G.N., KORPI,E.R.,FREED,M.J.,ZALCHMAN,S.J., BtGELOW,L.B., 1985. Effect of valproic acid on behavior and plasma amino acid contentrations in chronic schizophrenic patients. Biol. Psychiatry -20: 209-215. KUTAY.F., 0NAT.T.. ERLACIN,S. (1983) Plasma, kas ve karacigerde serbest amino asidlerin gaz-likid kromatografisi ile analizi. E.D.T.F. dergisi, 22(4): 1007-16. MC GEER,P.L., ECCLES,J.C., MC GEER,E.G. (1979) Molecular Neurobiology of the Manzaalian Brain. pp: 199-230, Plenum Press, NewYork and London.
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MC GEER,P.L. and MC GEER, E.G. (1981) Amino acid neurotrasmitters. In: Basic Neuro-, chemistry,Siegel, G.J., Albers, R.W., Agranoff, B.W., Katzman, R. (Eds.) pp: 233-253, Little, Brown and company, Boston. MINARD,F.N. and MUSHAHVAR,L.K. (1966) Synthesis of gana butyric acid from a pool of glutamic acid in brain after decapitation. Life Sciences, 5: 1409-1413. NANOPOULOS,D., MAITRE,M., BELIN,M.F., AGUERO,M., PUJOL,J.F., GAMRANI,H., CALAS,A. (1981) Autoradiographic and immune cytochemical evidence for the existence of GABA-ergic neurons in the nucleus raphe dorsalis-possible existence of neurons containing 5HT lutamate decarboxylase. In: Amino Acid Neurotransmitters, F.V. De Feudis and P.Mantel 9 Eds.) pp: 519-525, Raven Press, NewYork. OKUMURA,N., OTSUKI,S., KAMEYAMA,A. J.Biochem. 47(3): 315-320.
(1960) Studies
on free amino acids
in human brain.
PERRY,T.L., BERRY.K., HANSEN,S., DIAMOND,S., MOK,C. (1971a) Regional distribution amino acids in human brain obtained at autopsy. J.Neurochem. -18: 513-519.
of
PERRY,T.L.,HANSEN,S., BERRY,K., MOK,C., LESK,D. (1971b) Free amino acids and related compounds in biopsies of human brain. J.Neurochem. -18: 521-528. PERRY,T.L. KISH,S.J., BUCHANON,J. (1979) Garena amino butyric of schizophrenic patients. Lancet, I: 237-239.
acid deficiency
in brain
PETERSON,N.A. and MC KEAN,C.M. (1969) The effects of individual amino acids on the corporation of labelled amino acids into proteins by brain homogenates. J.Neurochem. 16: 1211-1217. POTKIN,S.G., CANNON-SPOOR,H.E., De LISI,L.E., NECKERS,L.M., WYATT,R.J. (1983) Plasma phenylalanine, tyrosine and tryptophan in schizophrenia. Arch-Gen. Psychiatry. 40: 749-752. Inquiries
and reprint
requests
Dr.Fatma Z.KUTAY Assoc.Prof. of Biochemistry Ege University, Medical School Department of Biochemistry Bornova,fzmir TURKEY
should
be addressed
to: