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Chronic dietary lithium inhibits basal C-fos mRNA expression in rat brain
PTOLJNeuro~Psychopharmncol.
Pergamoa
& Biol. Psychiat. Copyright Printed
0278-5846(95)00235-Q
1995. Vol. 19. pp. 1177-I 0 1995 Elsevler
Science
187 Inc.
in Great Britain. All rights resewed 0278-
5846/95$2900
CHRONIC DIETARY LITHIUM INHIBITS BASAL C-Jos mFtNA EXPRESSION IN BAT BRAIN ALEKSANDER
A. MATHE’,
JEANNETTE
C. MILLER* and CARINA STENFORS’
’ Karolinska Institute, Institution of Clinical Neuroscience, Department of Psychiatry, St. Gorans Hospital, Stockholm, Sweden and ‘Millhauser Laboratories of the Department of Psychiatry, New York University Medical Center, New York, NY, USA and 3Karolinska Institute, Institution of Laboratory Medicine, Department of Ciinicai Chemistry, Karolinska Hospital, Stockholm, Sweden
(Final form, June 1995)
Abstract Math& Aleksander A., Jeannette C. Miller and Carina Stenfors: Chronic Dietary Lithium Inhibits Basal c-fos mRNA Expression in Rat Brain. Prog. Neuro-Psychopharmacol. & Biol. Psychiat. 1995,19(7): 1177-1187. 1. Lithium is the most effective prophylactic agent used in the treatment of bipolar disorder. Although the acute effects of lithium include an inhibitory action on the phosphatidylinositol (PI) system, the longer term effects on signal transduction processes linked to this system are poorly understood. 2. An important consequence of activation of receptors linked to the PI pathway is activation of protein kinase C (PKC), which is involved in the induction of the proto-oncogene, C-$X. 3. The authors hypothesized that chronic lithium treatment, by inhibiting signaling through the PYPKC pathway, might alter the expression of fos. 4. It was found that basal expression of c-fos was significantly reduced in cortical, hippocampal and hypothalamic brain areas of rats fed dietary lithium for 4 weeks. 5. The present results suggest that some of the effects of chronic lithium treatment may be mediated by alterations in signal transduction mechanisms linked tofos expression. Keywords: c-fix, depression,
lithium, mania, signal transduction.
Abbreviations: CAMP responsive element (CRE); CAMP responsive element binding protein (CREB); diacylglycerol (DAG); guanosine triphosphate (GTP); immediate early gene (IEG); inositol 1,4,5triphosphate (lP3); phosphatidyl inositol (PI); protein kinase A (PKA); protein kinase C (PKC); phospholipase C (PLC); serum response element (SRE); serum response factor (SRP)
1177
1178
A.A. MathP et al Introduction
The most conspicuous
clinical property
preventing both up and downward lithium produces
its anti-manic
of lithium is its “stabilizing” effect in major affective disorders,
mood oscillations in bipolar disorder. and anti-depressive
effects are not entirely understood,
ample literature on lithium’s effects on the phosphoinositol The PI cycle represents
an important
GTP dependent
hydrolysis
producing the second messengers, calcium, and diacylglycerol Berridge and Irvine, 1984).
4,5-biphosphate
inositol 1,4,5triphosphate
(DAG), which activates
although there is
that serve to modulate intracellular
1984). Neurotransmitters
of phosphatidylinositol
by which
(PI) system (Post and Chuang, 1991 review).
source of second messengers
calcium and protein kinase activity (Berridge,
The precise mechanisms
that activate the PI cycle induce
and activate phospholipase
C (PLC),
(IP3), an important mobilizer of intracellular
protein kinase C (PKC)
(Sherman,
1991 review and
There is evidence that lithium may produce its actions by reducing signaling
through these second messengers
(Lenox et al., 1992; Manji et al., 1991,1993) and by attenuating
G-
protein mediated function (Ebstein et al., 1980; Avissar et al., 1988; Belmaker et al., 1991; Li et al., 1991, 1993).
Recently,
attention
has been given to a possible
influence
of lithium on the proto-oncogene,
c-fos
because this gene is known to be rapidly activated by agonist signaling through the PLC/DAG/PKC adenylate cyclase/cAMP/cAMP-dependent other
protein kinase (PKA) second messenger
systems.
C-fos and
immediate early genes (IEGs) have been shown to play a role in neuronal cell function and are
induced in rat brain by a variety of neurotransmitters review). The fos and &n
protooncogenes
complex which binds cooperatively et al., 1988; Sassone-Corsi
encode
and extracellular stimuli (Morgan and Curran, 1991 nuclear phospho-proteins
that form a heterodimeric
to a DNA regulatory element known as the AP-1 binding site (Franza
et al., 1988a). This sequence has many variations and is present in both positive
and negative regulatory elements of a number of target genes (Rauscher et al., 1988; Gizang-Ginsberg Ziff, 1990) and thefos gene transcription
promoter
(Sassone-Corsi
signal transduction
et al., 1988b). thereby the potential to activate or repress
effects of the longer term consequences processes.
of chronic lithium treatment
Weiner et al., (1991) have previously
lithium treatment enhanced a muscarinic agonist induced c-fos response potential role for the IEGs in longer term adaptation expression,
particularly neuropeptides,
Because of the
of neuronal function and regulation of target gene
et al., 1994; Stenfors
the effect of chronic dietary lithium treatment
brain regions of the rat. Considering
on post
shown that subchronic
in the rat brain.
and the role that some neuropeptides
(Math6 et al., 1991, 1994; Jousisto-Hanson investigated
and
exists.
There are few established receptor
and
may play in mood disorders
et al., 1992,1994),
on the basal expression
of
the authors
c-fos in various
the apparent dampening effects of lithium on the PI pathway and on
G protein coupled function, the authors hypothesized
that lithium might reduce c-fos expression.
Clfos expression
1179
inhibited by lithium
Methods Animal Treatment Male Sprague-Dawley
rats (ALAB, Solna), initially weighing 120- 130 g, were used in all investigations.
The rats were housed at constant
room temperature
(21 f l”C), with a 12:12 hour light-dark cycle.
had free access to water, standard rat food or dietary lithium. weeks of dietary lithium) were examined in three experiments
The effects of (I, II and III).
chronic treatment
Rats (four
In the pilot experiment,
I.
three groups of animals (n=3 each) were fed identical amounts of standard rat chow, or chow to which lithium sulfate (Astra AB, Sodertalje)
in doses of 1.29 g/kg or 2.lY g/kg was admixed.
treatments were repeated in experiment
II (n=8,8,8) and in experiment
These lithium
III (n=S,5) in which only one dose
12.1Y g/kg) of lithium was given. In a separate mvestigation
using identical procedures
the mean serum lithium concentrations high lithium concentrations,
(Mathe et al., unpublished data) we showed that
were approximately
respectively.
0.4 and 0.6 mEq/L for the rats fed the low and
Along with regular tap water, all animals had free access to a
bottle containing 0.9% NaCl to prevent lithium toxicity (Ellis and Lenox, 1990). After the four week lithium regimen,
the animals were sacrificed
by decapitation,
the brains quickly
removed, and regions dissected according to Glowinsky and Iversen (1966). The tissues were immediately frozen in powdered dry ice and stored at -80°C until shipment for analysis of cTfos mRNA expression,
These studies were approved by the Ethical Committee all experiments,
the rats groomed
were observed.
No weight differences
for Animal Experiments,
Karolinska Institute.
In
normally and no gross behavioral changes or signs of lithium toxicity were observed in peripheral organs or in the brain regions between
the treatment groups (Mathk et al., 1994). Northern AnaIysis of c-fos mRNA Exoression Total RNA was prepared as previously described isothiocyanateCsC1 MOPS/formaldehyde (Stratalinker,
procedure
of Chirgwin
gels, and blotting
Stratagene,
La Jolla, CA).
(Miller, 1990) using a modification
et al. (1979).
onto nitrocelluose
After
of the guanidinium
electrophoresis
on 1% agarose
filters, the RNA was UV auto-cross-linked
The RNA blots were prehybridized
and hybridized
at 42°C as
previously described (Miller, 1990) with a 1.0 kb Pst I fragment of clfos cDNA (mouse) radiolabeled with ‘*P-dCTP (Random Primer Extension
System, DuPont, Boston, MA).
probe ranged from 1.3-2 x 10’ dpn+tg. simultaneously
The specific activity of the c-fos
RNA recovery for each sample was assessed
by reprobing
or
probing samples with a random primed 32P-dCTP labeled 564 bp fragment of rat cyclophilin
cDNA as a control “unregulated”
gene. Filters were washed to a stringency of 0.2 x standard saline citrate
buffer (1 X SSC = [0.15 M NaCl, 15 mM Na3Citrate-ZH?O])
in 0.1%
SDS for 1 hr at WC,
sealed in
1180
A.A. Math6 et al.
plastic bags and exposed to Kodak XAR-5 film for 18-36 hr. Data Analysis The intensity of hybridization the autoradiograms
using an Image Analysis Video Densitometric
c-fos were corrected sample.
for the mRNA species was quantitated
for recovery
The meanfislcyclophilin
data from the three experiments,
ANOVA
a fislcyclophilin
f sd. for each treatment group was calculated. thef’slcyclophilin
analysis of
The density units for
System (MCID).
and quantity of RNA by calculating
vehicle values (defined as 100% k s.d.) using either one-way
by video densitometric
ratio for each
In order to combine the
ratios of the lithium treated samples were compared to
to calculate percent of control.
and post hoc comparisons
Statistical analyses were made
by the Student-Newman-Keuls
procedure
(Sigmastat) or the Student’s t-test (Sigmastat).
The results of chronic lithium exposure
on c-fos expression
are shown in Table 1. In experiment I, no
significant effect of chronic lithium was found in the frontal cortex, striatum or hypothalamus,
Significant reductions in c-
there was an overall tendency of lithium to reduce c-fos mRNA in these areas. fos mRNA were found, however,
in the occipital cortex and hippocampus.
although
In experiment
II, both doses
of dietary lithium significantly reduced c-fos in frontal cortex, occipital cortex, striatum and hippocampus, but no significant effect was seen in the hypothalamus. higher dose of lithium in the pituitary. experiment
III,
hippocampus;
A dose-related
A significant reduction
no significant
effect was seen in occipital cortex,
in the frontal cortex and striatum
or pituitary.
Northern blots from experiment
III are shown in Fig. 1. When all the data were combined,
found to significantly
c-fos expression
hypothalamus
decrease
(Fig. 2). A dose-related
In
effect was only observed in the hippocampus.
lithium was again found to reduce c-fos mRNA expression however
was only seen with the
in frontal cortex,
occipital
cortex,
The
lithium was
hippocampus
and
effect was only evident in the hippocampus.
Discussion Short and Long-term Effects of Lithium on c-fos The major finding from this study is that chronic lithium treatment reduces the &@ expression in cortical, hippocampal perturbation.
and hypothalamic
of c-fos
brain areas of rats in the absence of any pharmacological
To date only a few papers on the effects of lithium on c-fos have been published.
Weiner et
al. (1991) reported that acute and subchronic lithium treatment of rats enhances cortical c-fos expression elicited by muscarinic, Ml, receptor response
is attenuated
activation; however this lithium augmenting of an agonist mediated
with repeated lithium treatment,
a result consistent with the refractoriness
of fos
C-fos expression
inhibited
by lithium
1181
Table 1 Effect of Chronic Dietary Lithium on c-fos Expression
Frontal Cortex Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) occipital cortex Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) Striatum Expt. I (n=3,3,3) Expt. II (n=7,7,7) Expt. III (n=5,5) Hippocampus Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) Hypothalamus Expt. I (n=3,3,3) Expt. II (n=4,3,3) Expt. III (n=5,5) Pituitary Expt. II (n=3,4,4) Expt. III (n=4,4)
0.768 k 0.034 0.606 + 0.128 0.212 f 0.040
0.722kO.100 0.507 f 0.052* ND
0.758 + 0.072 0.498 f 0.02 1* 0.117 f 0.078*
0.880 k 0.117 0.540 * 0.045 0.539 + 0.102
0.614 f 0.062* 0.460 f 0.053* ND
0.725 f 0.040 0.467 f 0.039* 0.413+0.110
1.161 f0.235 0.626 + 0.030 0.264 f 0.039
1.138 f0.099 0.525 f 0.055* ND
1.293 f 0.256 0.505 f 0.049* 0.274 + 0.037
0.7 12 + 0.060 0.918 + 0.044 0.25 1 + 0.040
0.599 f 0.018* 0.861 + 0.055* ND
0.6 15 + 0.050* 0.804 + 0.042*# 0.191 f 0.025*
0.733 k 0.042 0.576 k 0.104 0.498 rt 0.072
0.692 + 0.068 0.504 + 0.030 ND
0.633 + 0.054 0.526 + 0.094 0.377 f 0.038*
0.582 f 0.049 0.495 f 0.107
0.544 + 0.017 ND
0.508 zk0.029* 0.434 I!z0.134
Data reported as relative mEWA levels (c-fos/cyclopbilin). Experiments I and II, One-way ANOVA, posthoc comparison Student-Newman-Keuls method, *significantly different from vehicle treated, Pc.05; #significant lithium dose effect, P<.O5). Experiment III, Student’s t-test, *significantly different from vehicle treated, Pc.05.
induction
to repeated
treatment
may decrease
stimuli
in the CNS (Morgan and Curran, 1991). Thus, more prolonged
the fos response
lithium, per se, on c-fos expression
to agonists.
On the other hand, the longer term effects of
have apparently not been previously reported.
Lone Term Lithium Action on Signal Transduction
The molecular and/or genetic components
Pathways Linked to c-_os
contributing
to the expression
of manic depressive
not well understood
although a number of hypotheses
actions of lithium.
The most studied mechanism by which lithium is believed
effect in mood disorders
involves its effects
suggested that bipolar disorder
lithium
illness are
have been presented based on preclinical and clinical
on the PI/PKC
may be a result of overactivity
to exert
signal transduction of neurotransmitter
its therapeutic
pathway. signaling
It has been pathways
1182
A.A. Math6 et al.
Fig. 1. Northern Blots of c-fos mRNA Expression in Various Brain Regions After Chronic Dietary Lithium (f’rom Experiment III): 10 ttg of total RNA was analyzed from indicated brain regions [see Figure 2 for abbreviations] from rats after 4 weeks of standard rat chow (Vehicle treatment on the left) or 2.2 g/kg/day of lithium in the chow (Chronic lithium treatment on the right) as described in the text. The positions of 28s and 18s ribosomd RNAs, c-fos and cyclophilin are indicated. Each lane represents RNA analyzed from a single rat.
linked to the PYPKC second messenger
system (Lachman and Papalos, 1989; Hudson et al., 1993).
inhibition by lithium of the PI/PKC pathway and mobilization
of calcium might be expected to result in a
reduction or attenuation of PI linked neuronal activity, and in this way produce its therapeutic C-fos transcription
is highly regulated
and is subject to induction
systems and specific protein kinases which phosphorylate located in the promoter element
region of
(CRE), and serum response
(CAMP responsive 1991 review).
the fos gene. element
by activation
action..
of second messenger
proteins that converge on DNA regulatory sites,
Two important
sites are the Ca”-CAMP
(SRE) which recognize
element binding protein) and SRF (serum response
the transcription factor) respectively
responsive
factors CREB (Herschman,
There is substantial evidence from studies in cultured cells that signal transduction
in response to a number of different ligands (growth factors, serum, depolarization) the SRE or CRE elements of the fos promoter Activation of PKC-dependent
to induce its transcription
pathways results in fos induction mediates
cAMP/PKA
and Greenberg,
speculate
that decreased
pathways
appear to converge on
(Herschman,
199 1 for review).
mediated by transcriptional
bind to the SRE, while the CRE element 1990). Thus, the authors
Thus,
factors that
and calcium induction of c-fos (Sheng PKC activity by lithium might serve
C-,fos expression
2oo 2
/-
a
175-
m
E 5 0 ?J o\o v7 1=
150
-
125
-
100
-
inhibited
hy lithium
I183
___
CONTROL CHRONIC
Li (1 .3
CHRONIC
l.i (2 2 gm/kg)
FC
HT
gm/kq)
PIT
Fig. 2. Effect of Chronic Dietary Lithium on c-fos mRNA Expression in Various Brain Regions )41, = 5.628, Pc.007; Newman-Keuls, [Combined Data]. ANOVA revealed, FC = frontal cortex (F_, *P<.OS vs. control); OC = occipital cortex (F ~.4~)=I 1.738, Pc.001; NewmanKeuls, *P<.O5 vs. control); ST= striatum (FZ.XT= 2.455, P=O.lO); HC = hippocampus (F2,40=14.686, P<.OOl: Newman-Keuls, *P<.OS vs. control and “Pc.05 between doses); HT == hypothalamus (F?x,= 6.108, P=.OO7: Newman-Keuls, *P<.O5 vs. control); PIT = pituitary (F2.r6= 1.307, P=.298).
There
is support
for
this
hypothetical
to inhibit basal transcription
of C-$X.
lithium could affect c-f&.
Lenox et al. (1992) found a major reduction
products
in rat hippocampus
htppocampus
after chronic
although other mechanisms
such as regulation
by which
in two PKC phosphorylation
PKC activity has been observed
lithium and decreased
after lithium (Manji et al., 1993).
mechanism
in
Such actions of lithium may partly explain our tindings, of c-fos mRNA stability and the role of other factors,
including Fos and Fos related proteins, in repressing c-fos transcription
(Sassone-Corsi
et al., 1988b; Shaw
et al., 1989) cannot be ruled out.
There is also evidence suggesting
the potential for cross talk bctwcen the SRE and CRE elements of the
c-fos promoter which may be affected by lithium. Li et al. (1991) found a significant reduction in cortical Cc&l,
Gee-2 and Gs mRNAs from rats fed dietary lithium for 21 days.
decreased
levels of mRNA and protein for Gai- l,-2, but observed
How lithium affects the transcriptional known,
although
Cohn et al. (1991) also found
an upregulation
regulation of c-fos linked to the cAMPiPKA
Divish et al. (1991) reported
receptor activators of CAMP in PC12 cells.
no effect of
of adenylate cyclase. path in rat brain is not
lithium on c-fos expression
It is apparent from the data on G-protein
induced by
function, PKC and
cAMP activity, and the results of the present study that a clearer ptcturc of the mechanisms involved in the action of lithium, vis a vis c&s, contributions
requires
of both the cAMP/PKA
Functional Significance
further
and PJ/DAG/PKC
and a better- understandmg
signal-transduction
pathways.
Fos protein in specific neurons.
mouse have shown that Fos-1acZ fusion protein
neurons of the cortex and hippocampus
(Smeyne et al., 1992).
mechanisms.
expressed
in discretc
It would be of considerable
interest to
in these areas, particularly,
that are also altered by chronic lithium (Math6 et al., 1991, 1994;
et al., 1994; Zachrisson et al., 1995) and which may be targets for regulation by Fos/Jun
Although the specific neuronal sites at which the therapeutic
yet unknown, important
neuropeptides
Recent studies in thefos-
is continuously
determine whether chronic lithium affects Fos protein in neuronal populations
Jousisto-Hanson
the
in the present study, after chronic lithium, are relatively small and it is not
yet known whether such treatment also reduces
neurons expressing
of
of C-&X Reduction bv Chronic Lithium
The reductions seen in cfos,
/acZ transgene
investigation
the hippocampus,
subcortical
loci (Post et al., 1992 review).
actions of lithium occur are as
and cortical areas of the limbic system are almost certainly These areas are believed to be central to the expression
ot
emotion, mood and associative thinking, and may be disturbed in mania and depression,
Conclusion Chronic lithium treatment manner.
appears to reduce the basal expression
A reduction in c-fos expression
is compatible with previously observed attenuations
mediated function and in PKC mediated activity of the PI pathway. basal expression
of
clfos are biologically
mood remains to be determined. properties
in G-protein
Whether these modest reductions
significant or relevant to the stabilizing action of
Clinical effects
of lithium have a distinct
time course.
are apparent within one to two weeks following initiation of treatment,
effects in both mania and depression
require considerably
molecular events underlie these clinical phenomena. adaptations
of c-fos in brain in a region-specific
longer periods.
lithium on Anti-manic
while the prophylactic
It is conceivable
Further molecular characterizations
to chronic lithium could be helpful in the development
in
that different
of post receptor
of novel anti-manic and anti-depressant
drugs.
Acknowledemenis This study was supported
by the Swedish Medical Research Council 10414, the Theodore
Stanley Foundation, and the Karolinska Institute Research Fund.
and Vada
C-./bs rxpression
inhibitrd
by lithium
1185
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.J.l. (1992) Temporal and spatial expression Mol. Brain Res. 16: 1% 162.
of a ,fos-1ac.Z
STENFORS. C., SRINIVASAN, G.R., THEODORSSON, E. and MATH& A.A. (1992) Elcctroconvulsivc stimuli and brain peptides: effect of modification of seizure duration on neuropeptidc Brain Res. 5’)6:241-258. Y, ncurokinin A, substance P and neurotensin. STENFORS, C., MATHJ$ A.A. and THEODORSSON, E. (1994) Repeated changes in neuropeptide Y, neurotensin and tachykinin concentrations Psychopharmacol. & Biol. Psychiatry. u:201-209.
electroconvulstve in time. Prog.
WEINER, E.D., KALASAPUDI, V.D., PAPOLOS, D.F.. and LACHMAN, H.M. augments pilocarpine-induced fos expression in rat brain. Brain Res. 553: I 17-122.
(1991)
stimuli: Neuro-
Lithium
ZACHRISSON, O., MATH& A.A., STENFORS, C. and LINDEFORS, N. (1995) Region-specific effects of chronic lithium administration on neuropeptide Y and somatostatin mRNA expression in the rat brain. Neurosci. Lett., in press.
Inquiries and reprint requests should be addressed to:
Alcksander A. Math& M.D., Ph.D. Karolinska Institute Institution of Clinical Neuroscience Department of Psychiatry, St. Gorans Hospital, S - I 12 81 Stockholm, Sweden
Pergamoa
& Biol. Psychiat. Copyright Printed
0278-5846(95)00235-Q
1995. Vol. 19. pp. 1177-I 0 1995 Elsevler
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187 Inc.
in Great Britain. All rights resewed 0278-
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CHRONIC DIETARY LITHIUM INHIBITS BASAL C-Jos mFtNA EXPRESSION IN BAT BRAIN ALEKSANDER
A. MATHE’,
JEANNETTE
C. MILLER* and CARINA STENFORS’
’ Karolinska Institute, Institution of Clinical Neuroscience, Department of Psychiatry, St. Gorans Hospital, Stockholm, Sweden and ‘Millhauser Laboratories of the Department of Psychiatry, New York University Medical Center, New York, NY, USA and 3Karolinska Institute, Institution of Laboratory Medicine, Department of Ciinicai Chemistry, Karolinska Hospital, Stockholm, Sweden
(Final form, June 1995)
Abstract Math& Aleksander A., Jeannette C. Miller and Carina Stenfors: Chronic Dietary Lithium Inhibits Basal c-fos mRNA Expression in Rat Brain. Prog. Neuro-Psychopharmacol. & Biol. Psychiat. 1995,19(7): 1177-1187. 1. Lithium is the most effective prophylactic agent used in the treatment of bipolar disorder. Although the acute effects of lithium include an inhibitory action on the phosphatidylinositol (PI) system, the longer term effects on signal transduction processes linked to this system are poorly understood. 2. An important consequence of activation of receptors linked to the PI pathway is activation of protein kinase C (PKC), which is involved in the induction of the proto-oncogene, C-$X. 3. The authors hypothesized that chronic lithium treatment, by inhibiting signaling through the PYPKC pathway, might alter the expression of fos. 4. It was found that basal expression of c-fos was significantly reduced in cortical, hippocampal and hypothalamic brain areas of rats fed dietary lithium for 4 weeks. 5. The present results suggest that some of the effects of chronic lithium treatment may be mediated by alterations in signal transduction mechanisms linked tofos expression. Keywords: c-fix, depression,
lithium, mania, signal transduction.
Abbreviations: CAMP responsive element (CRE); CAMP responsive element binding protein (CREB); diacylglycerol (DAG); guanosine triphosphate (GTP); immediate early gene (IEG); inositol 1,4,5triphosphate (lP3); phosphatidyl inositol (PI); protein kinase A (PKA); protein kinase C (PKC); phospholipase C (PLC); serum response element (SRE); serum response factor (SRP)
1177
1178
A.A. MathP et al Introduction
The most conspicuous
clinical property
preventing both up and downward lithium produces
its anti-manic
of lithium is its “stabilizing” effect in major affective disorders,
mood oscillations in bipolar disorder. and anti-depressive
effects are not entirely understood,
ample literature on lithium’s effects on the phosphoinositol The PI cycle represents
an important
GTP dependent
hydrolysis
producing the second messengers, calcium, and diacylglycerol Berridge and Irvine, 1984).
4,5-biphosphate
inositol 1,4,5triphosphate
(DAG), which activates
although there is
that serve to modulate intracellular
1984). Neurotransmitters
of phosphatidylinositol
by which
(PI) system (Post and Chuang, 1991 review).
source of second messengers
calcium and protein kinase activity (Berridge,
The precise mechanisms
that activate the PI cycle induce
and activate phospholipase
C (PLC),
(IP3), an important mobilizer of intracellular
protein kinase C (PKC)
(Sherman,
1991 review and
There is evidence that lithium may produce its actions by reducing signaling
through these second messengers
(Lenox et al., 1992; Manji et al., 1991,1993) and by attenuating
G-
protein mediated function (Ebstein et al., 1980; Avissar et al., 1988; Belmaker et al., 1991; Li et al., 1991, 1993).
Recently,
attention
has been given to a possible
influence
of lithium on the proto-oncogene,
c-fos
because this gene is known to be rapidly activated by agonist signaling through the PLC/DAG/PKC adenylate cyclase/cAMP/cAMP-dependent other
protein kinase (PKA) second messenger
systems.
C-fos and
immediate early genes (IEGs) have been shown to play a role in neuronal cell function and are
induced in rat brain by a variety of neurotransmitters review). The fos and &n
protooncogenes
complex which binds cooperatively et al., 1988; Sassone-Corsi
encode
and extracellular stimuli (Morgan and Curran, 1991 nuclear phospho-proteins
that form a heterodimeric
to a DNA regulatory element known as the AP-1 binding site (Franza
et al., 1988a). This sequence has many variations and is present in both positive
and negative regulatory elements of a number of target genes (Rauscher et al., 1988; Gizang-Ginsberg Ziff, 1990) and thefos gene transcription
promoter
(Sassone-Corsi
signal transduction
et al., 1988b). thereby the potential to activate or repress
effects of the longer term consequences processes.
of chronic lithium treatment
Weiner et al., (1991) have previously
lithium treatment enhanced a muscarinic agonist induced c-fos response potential role for the IEGs in longer term adaptation expression,
particularly neuropeptides,
Because of the
of neuronal function and regulation of target gene
et al., 1994; Stenfors
the effect of chronic dietary lithium treatment
brain regions of the rat. Considering
on post
shown that subchronic
in the rat brain.
and the role that some neuropeptides
(Math6 et al., 1991, 1994; Jousisto-Hanson investigated
and
exists.
There are few established receptor
and
may play in mood disorders
et al., 1992,1994),
on the basal expression
of
the authors
c-fos in various
the apparent dampening effects of lithium on the PI pathway and on
G protein coupled function, the authors hypothesized
that lithium might reduce c-fos expression.
Clfos expression
1179
inhibited by lithium
Methods Animal Treatment Male Sprague-Dawley
rats (ALAB, Solna), initially weighing 120- 130 g, were used in all investigations.
The rats were housed at constant
room temperature
(21 f l”C), with a 12:12 hour light-dark cycle.
had free access to water, standard rat food or dietary lithium. weeks of dietary lithium) were examined in three experiments
The effects of (I, II and III).
chronic treatment
Rats (four
In the pilot experiment,
I.
three groups of animals (n=3 each) were fed identical amounts of standard rat chow, or chow to which lithium sulfate (Astra AB, Sodertalje)
in doses of 1.29 g/kg or 2.lY g/kg was admixed.
treatments were repeated in experiment
II (n=8,8,8) and in experiment
These lithium
III (n=S,5) in which only one dose
12.1Y g/kg) of lithium was given. In a separate mvestigation
using identical procedures
the mean serum lithium concentrations high lithium concentrations,
(Mathe et al., unpublished data) we showed that
were approximately
respectively.
0.4 and 0.6 mEq/L for the rats fed the low and
Along with regular tap water, all animals had free access to a
bottle containing 0.9% NaCl to prevent lithium toxicity (Ellis and Lenox, 1990). After the four week lithium regimen,
the animals were sacrificed
by decapitation,
the brains quickly
removed, and regions dissected according to Glowinsky and Iversen (1966). The tissues were immediately frozen in powdered dry ice and stored at -80°C until shipment for analysis of cTfos mRNA expression,
These studies were approved by the Ethical Committee all experiments,
the rats groomed
were observed.
No weight differences
for Animal Experiments,
Karolinska Institute.
In
normally and no gross behavioral changes or signs of lithium toxicity were observed in peripheral organs or in the brain regions between
the treatment groups (Mathk et al., 1994). Northern AnaIysis of c-fos mRNA Exoression Total RNA was prepared as previously described isothiocyanateCsC1 MOPS/formaldehyde (Stratalinker,
procedure
of Chirgwin
gels, and blotting
Stratagene,
La Jolla, CA).
(Miller, 1990) using a modification
et al. (1979).
onto nitrocelluose
After
of the guanidinium
electrophoresis
on 1% agarose
filters, the RNA was UV auto-cross-linked
The RNA blots were prehybridized
and hybridized
at 42°C as
previously described (Miller, 1990) with a 1.0 kb Pst I fragment of clfos cDNA (mouse) radiolabeled with ‘*P-dCTP (Random Primer Extension
System, DuPont, Boston, MA).
probe ranged from 1.3-2 x 10’ dpn+tg. simultaneously
The specific activity of the c-fos
RNA recovery for each sample was assessed
by reprobing
or
probing samples with a random primed 32P-dCTP labeled 564 bp fragment of rat cyclophilin
cDNA as a control “unregulated”
gene. Filters were washed to a stringency of 0.2 x standard saline citrate
buffer (1 X SSC = [0.15 M NaCl, 15 mM Na3Citrate-ZH?O])
in 0.1%
SDS for 1 hr at WC,
sealed in
1180
A.A. Math6 et al.
plastic bags and exposed to Kodak XAR-5 film for 18-36 hr. Data Analysis The intensity of hybridization the autoradiograms
using an Image Analysis Video Densitometric
c-fos were corrected sample.
for the mRNA species was quantitated
for recovery
The meanfislcyclophilin
data from the three experiments,
ANOVA
a fislcyclophilin
f sd. for each treatment group was calculated. thef’slcyclophilin
analysis of
The density units for
System (MCID).
and quantity of RNA by calculating
vehicle values (defined as 100% k s.d.) using either one-way
by video densitometric
ratio for each
In order to combine the
ratios of the lithium treated samples were compared to
to calculate percent of control.
and post hoc comparisons
Statistical analyses were made
by the Student-Newman-Keuls
procedure
(Sigmastat) or the Student’s t-test (Sigmastat).
The results of chronic lithium exposure
on c-fos expression
are shown in Table 1. In experiment I, no
significant effect of chronic lithium was found in the frontal cortex, striatum or hypothalamus,
Significant reductions in c-
there was an overall tendency of lithium to reduce c-fos mRNA in these areas. fos mRNA were found, however,
in the occipital cortex and hippocampus.
although
In experiment
II, both doses
of dietary lithium significantly reduced c-fos in frontal cortex, occipital cortex, striatum and hippocampus, but no significant effect was seen in the hypothalamus. higher dose of lithium in the pituitary. experiment
III,
hippocampus;
A dose-related
A significant reduction
no significant
effect was seen in occipital cortex,
in the frontal cortex and striatum
or pituitary.
Northern blots from experiment
III are shown in Fig. 1. When all the data were combined,
found to significantly
c-fos expression
hypothalamus
decrease
(Fig. 2). A dose-related
In
effect was only observed in the hippocampus.
lithium was again found to reduce c-fos mRNA expression however
was only seen with the
in frontal cortex,
occipital
cortex,
The
lithium was
hippocampus
and
effect was only evident in the hippocampus.
Discussion Short and Long-term Effects of Lithium on c-fos The major finding from this study is that chronic lithium treatment reduces the &@ expression in cortical, hippocampal perturbation.
and hypothalamic
of c-fos
brain areas of rats in the absence of any pharmacological
To date only a few papers on the effects of lithium on c-fos have been published.
Weiner et
al. (1991) reported that acute and subchronic lithium treatment of rats enhances cortical c-fos expression elicited by muscarinic, Ml, receptor response
is attenuated
activation; however this lithium augmenting of an agonist mediated
with repeated lithium treatment,
a result consistent with the refractoriness
of fos
C-fos expression
inhibited
by lithium
1181
Table 1 Effect of Chronic Dietary Lithium on c-fos Expression
Frontal Cortex Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) occipital cortex Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) Striatum Expt. I (n=3,3,3) Expt. II (n=7,7,7) Expt. III (n=5,5) Hippocampus Expt. I (n=3,3,3) Expt. II (n=8,8,8) Expt. III (n=5,5) Hypothalamus Expt. I (n=3,3,3) Expt. II (n=4,3,3) Expt. III (n=5,5) Pituitary Expt. II (n=3,4,4) Expt. III (n=4,4)
0.768 k 0.034 0.606 + 0.128 0.212 f 0.040
0.722kO.100 0.507 f 0.052* ND
0.758 + 0.072 0.498 f 0.02 1* 0.117 f 0.078*
0.880 k 0.117 0.540 * 0.045 0.539 + 0.102
0.614 f 0.062* 0.460 f 0.053* ND
0.725 f 0.040 0.467 f 0.039* 0.413+0.110
1.161 f0.235 0.626 + 0.030 0.264 f 0.039
1.138 f0.099 0.525 f 0.055* ND
1.293 f 0.256 0.505 f 0.049* 0.274 + 0.037
0.7 12 + 0.060 0.918 + 0.044 0.25 1 + 0.040
0.599 f 0.018* 0.861 + 0.055* ND
0.6 15 + 0.050* 0.804 + 0.042*# 0.191 f 0.025*
0.733 k 0.042 0.576 k 0.104 0.498 rt 0.072
0.692 + 0.068 0.504 + 0.030 ND
0.633 + 0.054 0.526 + 0.094 0.377 f 0.038*
0.582 f 0.049 0.495 f 0.107
0.544 + 0.017 ND
0.508 zk0.029* 0.434 I!z0.134
Data reported as relative mEWA levels (c-fos/cyclopbilin). Experiments I and II, One-way ANOVA, posthoc comparison Student-Newman-Keuls method, *significantly different from vehicle treated, Pc.05; #significant lithium dose effect, P<.O5). Experiment III, Student’s t-test, *significantly different from vehicle treated, Pc.05.
induction
to repeated
treatment
may decrease
stimuli
in the CNS (Morgan and Curran, 1991). Thus, more prolonged
the fos response
lithium, per se, on c-fos expression
to agonists.
On the other hand, the longer term effects of
have apparently not been previously reported.
Lone Term Lithium Action on Signal Transduction
The molecular and/or genetic components
Pathways Linked to c-_os
contributing
to the expression
of manic depressive
not well understood
although a number of hypotheses
actions of lithium.
The most studied mechanism by which lithium is believed
effect in mood disorders
involves its effects
suggested that bipolar disorder
lithium
illness are
have been presented based on preclinical and clinical
on the PI/PKC
may be a result of overactivity
to exert
signal transduction of neurotransmitter
its therapeutic
pathway. signaling
It has been pathways
1182
A.A. Math6 et al.
Fig. 1. Northern Blots of c-fos mRNA Expression in Various Brain Regions After Chronic Dietary Lithium (f’rom Experiment III): 10 ttg of total RNA was analyzed from indicated brain regions [see Figure 2 for abbreviations] from rats after 4 weeks of standard rat chow (Vehicle treatment on the left) or 2.2 g/kg/day of lithium in the chow (Chronic lithium treatment on the right) as described in the text. The positions of 28s and 18s ribosomd RNAs, c-fos and cyclophilin are indicated. Each lane represents RNA analyzed from a single rat.
linked to the PYPKC second messenger
system (Lachman and Papalos, 1989; Hudson et al., 1993).
inhibition by lithium of the PI/PKC pathway and mobilization
of calcium might be expected to result in a
reduction or attenuation of PI linked neuronal activity, and in this way produce its therapeutic C-fos transcription
is highly regulated
and is subject to induction
systems and specific protein kinases which phosphorylate located in the promoter element
region of
(CRE), and serum response
(CAMP responsive 1991 review).
the fos gene. element
by activation
action..
of second messenger
proteins that converge on DNA regulatory sites,
Two important
sites are the Ca”-CAMP
(SRE) which recognize
element binding protein) and SRF (serum response
the transcription factor) respectively
responsive
factors CREB (Herschman,
There is substantial evidence from studies in cultured cells that signal transduction
in response to a number of different ligands (growth factors, serum, depolarization) the SRE or CRE elements of the fos promoter Activation of PKC-dependent
to induce its transcription
pathways results in fos induction mediates
cAMP/PKA
and Greenberg,
speculate
that decreased
pathways
appear to converge on
(Herschman,
199 1 for review).
mediated by transcriptional
bind to the SRE, while the CRE element 1990). Thus, the authors
Thus,
factors that
and calcium induction of c-fos (Sheng PKC activity by lithium might serve
C-,fos expression
2oo 2
/-
a
175-
m
E 5 0 ?J o\o v7 1=
150
-
125
-
100
-
inhibited
hy lithium
I183
___
CONTROL CHRONIC
Li (1 .3
CHRONIC
l.i (2 2 gm/kg)
FC
HT
gm/kq)
PIT
Fig. 2. Effect of Chronic Dietary Lithium on c-fos mRNA Expression in Various Brain Regions )41, = 5.628, Pc.007; Newman-Keuls, [Combined Data]. ANOVA revealed, FC = frontal cortex (F_, *P<.OS vs. control); OC = occipital cortex (F ~.4~)=I 1.738, Pc.001; NewmanKeuls, *P<.O5 vs. control); ST= striatum (FZ.XT= 2.455, P=O.lO); HC = hippocampus (F2,40=14.686, P<.OOl: Newman-Keuls, *P<.OS vs. control and “Pc.05 between doses); HT == hypothalamus (F?x,= 6.108, P=.OO7: Newman-Keuls, *P<.O5 vs. control); PIT = pituitary (F2.r6= 1.307, P=.298).
There
is support
for
this
hypothetical
to inhibit basal transcription
of C-$X.
lithium could affect c-f&.
Lenox et al. (1992) found a major reduction
products
in rat hippocampus
htppocampus
after chronic
although other mechanisms
such as regulation
by which
in two PKC phosphorylation
PKC activity has been observed
lithium and decreased
after lithium (Manji et al., 1993).
mechanism
in
Such actions of lithium may partly explain our tindings, of c-fos mRNA stability and the role of other factors,
including Fos and Fos related proteins, in repressing c-fos transcription
(Sassone-Corsi
et al., 1988b; Shaw
et al., 1989) cannot be ruled out.
There is also evidence suggesting
the potential for cross talk bctwcen the SRE and CRE elements of the
c-fos promoter which may be affected by lithium. Li et al. (1991) found a significant reduction in cortical Cc&l,
Gee-2 and Gs mRNAs from rats fed dietary lithium for 21 days.
decreased
levels of mRNA and protein for Gai- l,-2, but observed
How lithium affects the transcriptional known,
although
Cohn et al. (1991) also found
an upregulation
regulation of c-fos linked to the cAMPiPKA
Divish et al. (1991) reported
receptor activators of CAMP in PC12 cells.
no effect of
of adenylate cyclase. path in rat brain is not
lithium on c-fos expression
It is apparent from the data on G-protein
induced by
function, PKC and
cAMP activity, and the results of the present study that a clearer ptcturc of the mechanisms involved in the action of lithium, vis a vis c&s, contributions
requires
of both the cAMP/PKA
Functional Significance
further
and PJ/DAG/PKC
and a better- understandmg
signal-transduction
pathways.
Fos protein in specific neurons.
mouse have shown that Fos-1acZ fusion protein
neurons of the cortex and hippocampus
(Smeyne et al., 1992).
mechanisms.
expressed
in discretc
It would be of considerable
interest to
in these areas, particularly,
that are also altered by chronic lithium (Math6 et al., 1991, 1994;
et al., 1994; Zachrisson et al., 1995) and which may be targets for regulation by Fos/Jun
Although the specific neuronal sites at which the therapeutic
yet unknown, important
neuropeptides
Recent studies in thefos-
is continuously
determine whether chronic lithium affects Fos protein in neuronal populations
Jousisto-Hanson
the
in the present study, after chronic lithium, are relatively small and it is not
yet known whether such treatment also reduces
neurons expressing
of
of C-&X Reduction bv Chronic Lithium
The reductions seen in cfos,
/acZ transgene
investigation
the hippocampus,
subcortical
loci (Post et al., 1992 review).
actions of lithium occur are as
and cortical areas of the limbic system are almost certainly These areas are believed to be central to the expression
ot
emotion, mood and associative thinking, and may be disturbed in mania and depression,
Conclusion Chronic lithium treatment manner.
appears to reduce the basal expression
A reduction in c-fos expression
is compatible with previously observed attenuations
mediated function and in PKC mediated activity of the PI pathway. basal expression
of
clfos are biologically
mood remains to be determined. properties
in G-protein
Whether these modest reductions
significant or relevant to the stabilizing action of
Clinical effects
of lithium have a distinct
time course.
are apparent within one to two weeks following initiation of treatment,
effects in both mania and depression
require considerably
molecular events underlie these clinical phenomena. adaptations
of c-fos in brain in a region-specific
longer periods.
lithium on Anti-manic
while the prophylactic
It is conceivable
Further molecular characterizations
to chronic lithium could be helpful in the development
in
that different
of post receptor
of novel anti-manic and anti-depressant
drugs.
Acknowledemenis This study was supported
by the Swedish Medical Research Council 10414, the Theodore
Stanley Foundation, and the Karolinska Institute Research Fund.
and Vada
C-./bs rxpression
inhibitrd
by lithium
1185
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Inquiries and reprint requests should be addressed to:
Alcksander A. Math& M.D., Ph.D. Karolinska Institute Institution of Clinical Neuroscience Department of Psychiatry, St. Gorans Hospital, S - I 12 81 Stockholm, Sweden