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Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain
Journal Pre-proofs Research report Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain Nozomu Takaki, Tatsuhiro Uchiwa, Mitsuhiro Furuse, Shinobu Yasuo PII: DOI: Reference:
S0006-8993(20)30081-0 https://doi.org/10.1016/j.brainres.2020.146725 BRES 146725
To appear in:
Brain Research
Received Date: Revised Date: Accepted Date:
20 January 2019 26 October 2019 10 February 2020
Please cite this article as: N. Takaki, T. Uchiwa, M. Furuse, S. Yasuo, Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain, Brain Research (2020), doi: https://doi.org/10.1016/j.brainres. 2020.146725
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1
Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain
2 3
Nozomu Takaki, Tatsuhiro Uchiwa, Mitsuhiro Furuse, Shinobu Yasuo
4 5
Laboratory of Regulation in Metabolism and Behavior, Faculty of Agriculture, Kyushu
6
University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan
7 8
Corresponding author: Shinobu Yasuo, Ph.D.
9
Laboratory of Regulation in Metabolism and Behavior, Faculty of Agriculture, Kyushu-
10
University
11
744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan
12
Phone/Fax: +81-92-802-4597
13
E-mail: [email protected]
14 15
Abbreviations: 5-hmC, 5-hydroxymethylcytosine; 5-mC, 5-methylcytosine; DG, dentate
16
gyrus; DNMT, DNA methyltransferase; HC, hippocampus; LD, long-day; OB, olfactory
17
bulb; P, postnatal days; SD, short-day; SSC, saline sodium citrate; TET, ten-eleven
18
translocation; ZT, Zeitgeber time.
1
19
Abstract
20
Season of birth influences the onset of psychiatric diseases in mammals. Recent studies
21
using rodent models have revealed that photoperiod during early life stages has a strong
22
impact on affective and cognitive behaviors, neuronal activity, and hippocampal
23
neurogenesis/astrogenesis in later life. The present study examined the effect of postnatal
24
photoperiod on global DNA methylation and hydroxymethylation dynamics in the mouse
25
brain. Male mice born under short-day (SD) conditions were divided into SD and long-
26
day (LD) groups on the day of birth. Temporal expression of DNA methyltransferases
27
(DNMT1/3a) with 5-methylcytosine (5-mC) levels, as well as protein levels of ten-eleven
28
translocation (TET) 2 with 5-hydroxymethylcytosine (5-hmC) levels, were analyzed from
29
postnatal day 4 (P4) to P21. Levels of 5-hmC in all hippocampal areas were higher in the
30
LD group than in the SD group at P21, with a positive correlation between 5-hmC levels
31
and TET2 levels throughout the experimental period. Inconsistent results were observed
32
between DNMT1/3a mRNA levels and 5-mC levels. On the other hand, in the OB, mRNA
33
levels of DNMT1 and DNMT3a were slightly lower in the LD group similar to 5-mC
34
levels, but TET2 and 5-hmC levels were not influenced by the photoperiod. In conclusion,
35
postnatal exposure of mice to LD conditions induces an increase in TET2-dependent
36
DNA hydroxymethylation in the hippocampus, which might be involved in the long-term
37
effects of postnatal photoperiod on neurogenesis and affective/cognitive behaviors.
38 39
Keywords: DNA methyltransferase; Ten-eleven translocation; Hippocampus; 5-
40
Methylcytosine; 5-Hydroxymethylcytosine
2
41
1. Introduction
42
Seasonal changes in photoperiod influence various physiological functions and
43
behaviors in mammals, including reproduction, energy homeostasis, neuroplasticity, and
44
affective/cognitive behaviors (Dardente et al., 2019; Prendergast and Nelson, 2005;
45
Walton et al., 2011). In addition, gestational and/or postnatal photoperiod has enduring
46
effects on physiological and behavioral phenotypes; pre- and/or postnatal exposure to
47
short-day (SD) condition increases anxiety- and/or depression-like behaviors in Siberian
48
hamsters (Pyter and Nelson, 2006), rats (Toki et al., 2007), and C3H mice (Green et al.,
49
2015). Our previous studies demonstrated that C57BL/6J mice are a useful strain for the
50
study of photoperiodic regulation in affective behaviors, evidenced by the photoperiodic
51
changes in depression-like behaviors and related functions (Otsuka et al., 2012; Otsuka
52
et al., 2014). We have further clarified that photoperiod during early life stages altered
53
prepulse inhibition and depression-like behavior in adult C57BL/6J mice (Takai et al.,
54
2018). The critical window in rodents appears to be the early postnatal period (Takai et
55
al., 2018; Uchiwa et al., 2016), which is equivalent to the third trimester of pregnancy in
56
humans in terms of brain development (Clancy et al., 2007). The hippocampus represents
57
one of the photoperiod-programmable regions, given that pre- and postnatal photoperiod
58
alter the proliferation of neural stem cells and astrogenesis in the dentate gyrus (DG), as
59
well as expression of glucocorticoid receptors in later life (Takai et al., 2018; Toki et al.,
60
2007). These reports suggest that epigenetic mechanisms are involved in the long-term
61
effect of photoperiod over life stages, which may be related to the association between
62
birth season and the onset of psychiatric diseases, including schizophrenia, bipolar
63
disorder, and seasonal affective disorder in humans (Foster and Roenneberg, 2008).
64
DNA methylation is one of the major epigenetic modification systems and has
3
65
important roles in neurodevelopmental or psychiatric diseases. For example, inhibition of
66
DNA methylation in the hippocampus demonstrated anti-depressant-like effects (Sales et
67
al., 2011), and DNA methylation on peripheral blood DNA was associated with traits of
68
autism (Wong et al., 2014), and schizophrenia (Dempster et al., 2011). DNA methylation
69
occurs by the addition of a methyl group to C5 position of cytosine to form 5-
70
methylcytosine (5-mC), catalyzed by a family of DNA methyltransferases (DNMTs). De
71
novo methylation is catalyzed by DNMT3a and DNMT3b, while DNMT1 maintains the
72
pattern of methylation when DNA duplicates (Johnson et al., 2012). Alternately, ten-
73
eleven translocation (TET) proteins (TET1, TET2, and TET3) are involved in the DNA
74
demethylation
75
hydroxymethylcytosine (5-hmC), 5-formylcytosine and 5-carboxylcytosine (Wu and
76
Zhang, 2017). Approximately 60 - 80% of CpG sites in the mammalian genome are
77
modified to 5-mC, and 5-hmC accounting for roughly 40% of the modified cytosine in
78
the brain (Kriaucionis and Heintz, 2009; Smith and Meissner, 2013). Methylation of CpG
79
islands plays a role in silencing of transcription and heterochromatin formation (Smith
80
and Meissner, 2013). Recent studies further clarified that 5-hmC is not only an
81
intermediate of demethylation process, but also has specific functions, such as promotion
82
of transcription and chromatin accessibility via a 5-hmC-binding protein (Mellén et al.,
83
2012). Epigenetic modification by 5-hmC is associated with neurodevelopment and
84
diseases; 5-hmC levels in the hippocampus are decreased in patients with Alzheimer's
85
disease (Chouliaras et al., 2013), and 5-hmC levels in the cerebellum are inversely
86
correlated with the levels of methyl-CpG-binding protein 2, a protein responsible for Rett
87
syndrome (Szulwach et al., 2011).
88
process,
catalyzing
the
conversion
from
5-mC
into
5-
Developmental changes in the expression of DNMTs in the brain have been reported
4
89
in rats. The expression levels of DNMTs were highest during the first week of life and
90
decreased gradually until 3 weeks postnatally, although global DNA methylation levels
91
did not follow this expression pattern (Simmons et al., 2013). It was also reported that
92
neuronal cells in mice acquire 5-hmC from postnatal neurodevelopment through
93
adulthood (Szulwach et al., 2011). Environmental factors such as caregiver maltreatment
94
and dietary conditions alter 5-mC and 5-hmC levels in the hippocampus, amygdala, or
95
thalamus (Doherty et al., 2016; Weng et al., 2014) suggesting that DNA methylation
96
dynamics may be additionally modified by early postnatal photoperiod. Therefore, in this
97
study we analyzed the effect of early postnatal photoperiod on the mRNA or protein levels
98
of DNMTs and TETs, as well as global 5-mC and 5-hmC levels in the C57BL/6J mouse
99
brain. For the analysis of TETs, we focused on TET2 due to the strong impact of TET2
100
in neurogenesis and memory (Gontier et al., 2018).
5
101
2. Results
102
2.1.
The mRNA expression of DNMT1 and DNMT3a
103
Expressions of both DNMT1 and DNMT3a were most prominent in the hippocampus
104
and olfactory bulb (OB) as observed by in situ hybridization (Fig. 1A). Therefore, we
105
measured their mRNA levels in these particular regions. Overall, the mRNA levels of
106
DNMT1 in the hippocampus and OB were lower in the long-day (LD) group compared
107
with its levels in the SD group (Fig. 1B). A statistically significant difference was detected
108
in the OB (F(1,17)=13.73, p < 0.01), and a trend was observed in the DG (F(1,17)=4.42,
109
p = 0.0506). Moreover, the effect of age was significant in all regions (DG: F(2,17)=6.42,
110
CA1: F(2,16)=10.83, OB: F(2,17)=8.83, p < 0.01, CA3: F(2,16)=5.62, p < 0.05); the
111
mRNA levels of DNMT1 decreased with increasing age (Fig. 1B). No significant
112
interaction between photoperiod and age was detected in any of the regions examined.
113
The mRNA levels of DNMT3a in the hippocampus and OB were also lower in LD group
114
compared with its levels in the SD group (Fig. 1B). The main effect of photoperiod was
115
detected in the CA3 (F(1,17)=11.00, p < 0.01) and OB (F(1,17)=6.74, p < 0.05). However,
116
neither the effect of age nor the interaction between photoperiod and age were significant
117
in any of the regions analyzed. The mRNA levels of neither DNMT1 nor DNMT3a in the
118
hippocampus and OB in the 21-day-old (P21) mice were affected by the photoperiod (data
119
not shown).
120 121
2.2.
Global levels of 5-mC and 5-hmC
122
5-mC was clearly detected by immunostaining in the DG and OB of P4 and P10 mice.
123
However, in CA1 and CA3 at the same ages, 5-mC levels were too weak to analyze (Fig.
124
2A). Moreover, weak 5-mC signals were observed in the brains of P21 mice (data not
6
125
shown). Therefore, we quantified 5-mC signals only in the DG and OB of P4 and P10
126
mice. Our results demonstrated that there was no significant difference in 5-mC levels in
127
the DG between mice of the LD and SD group (Fig. 2B). However, 5-mC levels in the
128
OB were significantly lower in the mice under LD condition compared with those under
129
SD (F(1,19)=4.92, p < 0.05, Fig. 2B). Additionally, the effect of age on 5-mC levels was
130
significant in the DG (F(1,19)=6.24, p < 0.05), but not in the OB. No significant
131
interaction was detected between photoperiod and age.
132
Further, 5-hmC was clearly detected by immunostaining in the hippocampus and OB
133
of P4, P10, and P21 mice (Fig. 3A). 5-hmC levels in the DG and CA3 were not
134
significantly different between LD and SD groups, while those in CA1 were significantly
135
higher in the LD group compared with those in the SD group (F(1,28) =6.28, p < 0.05,
136
Fig. 3B). Post-hoc analysis clarified that 5-hmC levels in the LD group were significantly
137
higher compared with those in the SD group in all hippocampal regions of P21 mice (p <
138
0.01; Fig. 3B). Moreover, the effect of age on 5-hmC levels was significant in all
139
hippocampal regions (DG: F(2,29)=11.32, CA1: F(2,28)=40.67, CA3: F(2,29)=60.49, p
140
< 0.001); 5-hmC levels decreased with increasing age in the hippocampus, whereas they
141
increased with increasing age in the OB (Fig. 3B). Furthermore, significant interactions
142
between photoperiod and age were detected in all hippocampal regions (DG:
143
F(2,29)=6.31, CA3: F(2,29)=8.43, p < 0.01; CA1: F(2,28)=4.63, p < 0.05). The levels of
144
5-hmC in the OB were not significantly different between LD and SD groups at any age
145
(Fig. 3B).
146 147 148
2.3.
TET2 protein levels
TET2 immunosignals were clearly detected in the hippocampus and OB (Fig. 3A).
7
149
Signals in all regions were not significantly different between LD and SD groups (Fig.
150
3B). The main effect of age on TET2 levels was significant in all brain regions examined
151
(DG: F(2,28)=17.59, CA1: F(2,27)=46.51, CA3: F(2,29)=62.71, p < 0.001; OB:
152
F(2,30)=3.60, p < 0.05). Similar to 5-hmC levels, TET2 levels decreased or increased
153
with increasing age in the hippocampus and OB, respectively (Fig. 3B). A statistically
154
significant interaction between photoperiod and age was detected in all hippocampal
155
regions (DG: F(2,28)=4.22, CA1: F(2,27)=4.97, p < 0.05; CA3: F(2,29)=7.62, p < 0.01).
156
Post-hoc analysis demonstrated that TET2 levels were significantly lower in the LD group
157
compared with those in the SD group in the DG and CA3 of P4 mice (DG: p < 0.05, CA3:
158
p < 0.01).
159
The photoperiod- and age-dependent trends were similar for 5-hmC and TET2 levels;
160
therefore, we sought to analyze the correlation between them. Indeed, we found strong
161
correlations between TET2 and 5-hmC levels in the DG (p < 0.0001, r = 0.709, Fig. 3B),
162
CA1 (p < 0.0001, r = 0.892, Fig. 3B), and CA3 (p < 0.0001, r = 0.938, Fig. 3B). On the
163
other hand, the correlation between TET2 levels and 5-hmC levels in the OB was rather
164
weak (p < 0.05, r = 0.403, Fig. 3B).
8
165
3. Discussion
166
The present study demonstrated, for the first time, that early postnatal photoperiod
167
alters DNA methylation and hydroxymethylation dynamics in the hippocampus and OB
168
in a region-specific manner. Furthermore, exposure of mice to LD conditions induces an
169
increase in the DNA hydroxymethylation marker (5-hmC) in the hippocampus and a
170
decrease in the DNA methylation marker (5-mC) in the OB. Importantly, these changes
171
reflect the changes in the mRNA expression or protein levels of regulatory enzymes.
172
Hippocampal TET2 and 5-hmC levels showed a positive correlation, as observed in the
173
comparison between young and aged mice (Gontier et al., 2018) and the promotor region
174
of miR-137 between sedentary and exercise groups in aged mice (Jessop and Toledo-
175
Rodriguez, 2018). In the OB, the mRNA levels of DNMT1 and DNMT3a were lower in
176
the LD group, similar to that of 5-mC levels, although the physiological consequences
177
remain unclear. DNA methylation status in the OB is linked to odor location memories
178
in injured mice (Tajerian et al., 2019), suggesting a modulatory role of postnatal
179
photoperiod in sensory systems.
180
A previous study reported that exposure of adult animals to different photoperiods
181
alters DNMTs expression in Siberian hamsters, in which DNMT3a expression in the
182
hypothalamus was higher in hamsters under LD condition than in those under SD
183
(Stevenson, 2017). Another study using adult male and female Siberian hamsters
184
demonstrated that DNMT3a expression in the testis and uterus was higher in animals
185
exposed to SD than in those exposed to LD, with higher global 5-mC levels in the testis
186
(Lynch et al., 2016). The present study is the first to demonstrate the effect of early
187
postnatal photoperiod on DNA methylation/hydroxymethylation associated measures,
188
including DNMTs expression. Furthermore, the results observed in the hippocampus and
9
189
OB were different from those of other tissues in animals exposed to photoperiods during
190
adulthood. Taken together, the effect of photoperiod on the expression of DNMTs and 5-
191
mC levels appears to be brain-region specific and, on the other hand, to depend on the
192
organ, age, and sex examined in each study.
193
The physiological impact of the early postnatal photoperiod-dependent modulation of
194
DNA methylation/hydroxymethylation is not clear in the present study. One possible
195
explanation is the influence on hippocampal neurogenesis and related behaviors in later
196
life, which have been shown to be modulated by early postnatal photoperiod in mice, rats,
197
and hamsters (Green et al., 2015; Pyter and Nelson, 2006; Takai et al., 2018; Toki et al.,
198
2007). Deficiency of dietary methyl-donors in adolescence resulted in impaired learning
199
and memory, and decreased expression of glutamate receptors with specific CpG
200
hypermethylation (Tomizawa et al., 2015). In adult rats bred for low response to novelty,
201
increased dietary methyl-donor content ameliorated anxiety-like behaviors and decreased
202
immobility in the forced swim test (McCoy et al., 2017). In addition, 5-hmC abundance
203
increased with neural stem cell differentiation, accompanied by increased TET2 protein
204
levels (Li et al., 2017). Thus, age-dependent changes in TET2 and 5-hmC levels in the
205
hippocampus are positively associated with neurogenesis and cognitive functions
206
(Gontier et al., 2018; Jessop and Toledo-Rodriguez, 2018). Notably, the present study
207
clarified higher levels of 5-hmC and TET2 in the hippocampus of the LD group,
208
compared with those in the SD group, which is in agreement with the higher levels of
209
neurogenesis in animals bred under LD (Takai et al., 2018). Mechanisms underlying
210
postnatal photoperiod-induced changes in 5-hmC/TET2 levels remain unclear. TET2
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proteins can be regulated by calpains, a family of calcium-dependent proteases (Wang
212
and Zhang, 278). Calpain activity in hippocampal cells is modulated by glucocorticoid
10
213
and retinoic acid signaling (Roumes et al., 2016), both which are under the control of
214
photoperiod (Otsuka et al., 2012; Dardente et al., 2019), suggesting a possible role in the
215
regulation of TET2 protein levels.
216
One of the cellular functions of DNA methylation/hydroxymethylation system is
217
transcriptional regulation. At the molecular level, our previous study showed that early
218
postnatal photoperiod alters the expression of a glucocorticoid receptor (Nr3c1) in the
219
hippocampus (Takai et al., 2018). The present study revealed that postnatal photoperiod
220
induced changes in DNA hydroxymethylation in the hippocampus. These data suggest
221
that
222
methylation/hydroxymethylation dynamics as a consequence of photoperiodic conditions,
223
given that DNA methylation of Nr3c1 is highly sensitive to stress and glucocorticoid, a
224
photoperiod-controlled hormone (Otsuka et al., 2012). For example, repetitive restrain
225
stress on rats decreased global methylation levels in the hippocampus with decreased
226
expression of Nr3c1 (Makhathini et al., 2017), and acute stress increased 5-hmC levels
227
of Nr3c1 promoter in the mouse hippocampus (Li et al., 2015). Embryonic exposure to
228
high dose of corticosterone increased DNA methylation of the hypothalamic Nr3c1 gene
229
in the chicken (Ahmed et al., 2014). However, we have no data about the effect of early
230
postnatal photoperiod on methylation/hypermethylation levels in specific genes, nor
231
genomic distribution of their markers, which needs to be studied in future.
the
altered
expression
of
Nr3c1
may
be
caused
by
DNA
232
In the present study, expression of DNMT1 and DNMT3a and 5-mC levels in both the
233
hippocampus and OB decreased with age. These observations are in congruence with the
234
report using rats, in which expression of DNMTs and 5-mC levels gradually decreased
235
from birth to P21 in the hippocampus (Simmons et al., 2013). The present study also
236
showed an age-dependent decrease in 5-hmC and TET2 protein levels in the hippocampus,
11
237
in line with findings of a previous study, showing that 5-hmC and TET2 levels decreased
238
with age, at least until the age of 18 months, and affected neurogenesis and memory in
239
mice (Gontier et al., 2018). On the other hand, we uncovered unexpected results in the
240
OB, in which 5-hmC and TET2 levels increased with age. Brain area-specific patterns of
241
age-dependent 5-hmC and TET2 levels may be related with different timing of postnatal
242
synaptogenesis and neurogenesis between the hippocampus and the OB; synaptogenesis
243
and neurogenesis in the DG is most active between P7 and P30 (O'Kusky et al., 2000;
244
Steward and Falk, 1986), while the OB grows steadily in size from birth to maturity, until
245
the age of 12 weeks (Pomeroy et al., 1990).
246
In conclusion, here we demonstrated that the photoperiod during early postnatal life
247
differentially alters DNA methylation and hydroxymethylation systems in the mouse
248
hippocampus and OB. In the hippocampus, the photoperiod possibly alters global 5-hmC
249
levels by modulating TET2 protein levels. In the OB, global 5-mC levels were regulated
250
by the photoperiod and similar changes were observed in the expression of DNMTs.
251
These changes may have long-term effects on neurogenesis and affective/cognitive
252
behaviors.
253 254
Conflict of interest
255
The authors declare that they have no conflict of interest.
256 257
Acknowledgement
258
This study was supported by Grants-in-Aid for Challenging Exploratory Research
259
(No.17K19914) to S.Y. from the Japanese Society for the Promotion of Science.
12
260
4. Experimental procedure
261
4.1.
Animals
262
The study was conducted according to the Guidelines for Animal Experiments by the
263
Faculty of Agriculture in Kyushu University, following the law No. 105 and Notification
264
No. 6. All animal experiments reported here were conducted in accordance with the as
265
well as All experiments were approved by Animal Care and Use Committee of Kyushu
266
University (A28-069-0). Mice were maintained in a light-tight box placed in a room at
267
the temperature of 25 ± 1°C. Water and standard diet for laboratory rodents (MF, Oriental
268
Yeast, Tokyo, Japan) were available ad libitum and were replenished at least once a week.
269
Male and female 6-week-old C57BL/6J mice obtained from Japan SLC, Inc. were
270
separately housed in groups of 3 or 4 animals under SD (6 h light - 18 h dark, 6L18D) for
271
more than 3 weeks. Thereafter they were mated under SD and the offsprings with their
272
mothers and littermates were randomly separated into 2 groups on the day of birth: SD
273
and LD (18 h light - 6 h dark, 18L6D) groups. Both groups included offsprings from 2 -
274
4 litters in each age. This study used the SD condition, not 12L12D, for acclimation and
275
control for the following reasons: 1) the shifts from 12L12D to SD and from 12L12D to
276
LD are opposite to each other with regard to the photoperiodic response and have been
277
suggested to involve distinct mechanisms; thus, it would be difficult to compare the
278
outcomes (Yasuo et al., 2010); 2) 12L12D was interpreted as a stimulatory LD condition
279
in F344 rats (Tavolaro et al., 2015) and, thus, the effect of LD would not be precisely
280
evaluated. Therefore, we used SD as the control condition and focused on the stimulatory
281
effect of LD.
282
For in situ hybridization, the offsprings at P4, P7, P10 and P21 (n = 3 - 4, including
283
offsprings from more than 2 litters for each age) were euthanized by isoflurane gas and
13
284
decapitated at Zeitgeber time (ZT; ZT0 corresponds to light onset) 2. The brains were
285
collected and frozen with dry ice and stored in -80 °C until analysis. Because it was
286
difficult to quickly remove the skull of P4, P7, and P10 mice, their brains were frozen
287
with the skull. For immunohistochemistry, the offsprings at P4, P10 and P21 (n = 5 - 6,
288
including offsprings from more than 2 litters for each age) were euthanized by isoflurane
289
gas and decapitated at ZT2, and the brains were incubated with 4% paraformaldehyde for
290
12 h and cryoprotected with 20% sucrose at 4 °C. The brains were embedded in OCT
291
compound and frozen quickly. For both analyses, only male offsprings were used because
292
it is reported that the effect of early postnatal environment on DNA methylation in the
293
hippocampus is different between male and female rats (Doherty et al., 2016), and in the
294
previous studies on the effect of postnatal photoperiod male animals were often used
295
(Takai et al., 2018; Toki et al., 2007; Uchiwa et al., 2016). Therefore, the results of the
296
present and previous studies can be compared appropriately.
297 298
4.2.
In situ hybridization
299
Sagittal brain sections (18 μm-thick) were prepared using a cryostat (Leica, Wetzler,
300
Germany). Antisense and sense oligonucleotide probes for each gene (antisense: DNMT1:
301
5′-GGCCCACAGCGTTTCCGAGATGCCTGCTTGGTGGAATCCTTCCGA-3′;
302
DNMT3a:
303
GCCTCCAATGAAGAGTGGGTGCTCCAGGGTGACATTGAGGCTCCC-3′)
304
labeled with [33P]dATP (PerkinElmer, MA, US) by using terminal deoxynucleotidyl
305
transferase (Invitrogen, CA, US) at 37 °C for 2 h. The sections were fixed using 4%
306
paraformaldehyde in phosphate buffered saline for 10 min, and hybridization was carried
307
out overnight at 42 °C with 750,000 cpm of 33P-labeled probe for each slide. Two high-
5′-
14
were
308
stringency post-hybridization washes were performed at 55 °C. The sections were air-
309
dried and exposed to an X-ray film (Kodak, Tokyo, Japan) for 2 weeks with 14C-labeled
310
standards (American Radiolabeled Chemicals, MO, US). Sense probes detected no
311
signals for either DNMT1 or DNMT3a. We also performed the analysis for DNMT3b and
312
TET2 expression, but signals were too weak to analyze (data not shown).
313
Relative optical densities of signals were measured using a computed image analysis
314
system (ImageJ, National Institutes of Health, http://imagej.nih.gov/ij) and were
315
converted into the relative radioactivity units (Bq/mg) by using the 14C-labeled standards.
316
Two sections including the hippocampus and OB were selected from each animal for each
317
gene, and signals in the DG, CA1, CA3, and OB were analyzed. In each section,
318
background values obtained from adjacent brain areas that did not exhibit a hybridization
319
signal were subtracted. Signals from two sections were averaged in each animal.
320 321
4.3.
Immunohistochemistry
322
Sagittal cryostat sections (20 μm-thick) including the hippocampus and OB were
323
prepared. For immunostaining of 5-mC and 5-hmC, the sections were dried and soaked
324
sequentially in 1.5% hydrogen peroxide in methanol for 10 min, 50% formamide/2 ×
325
saline sodium citrate (SSC) at 65 °C for 30 min, 2 × SSC for 5 min, 1 N hydrochloric acid
326
at 37 °C for 30 min, and 0.1 M boric acid (pH 8.5) for 10 min. The sections were then
327
incubated with 10% normal goat serum for 30 min. Thereafter, the sections were
328
incubated overnight with rabbit monoclonal anti-5-mC antibody (1:800, Cell Signaling
329
Technology, Danvers, MA) or rabbit polyclonal anti-5-hmC antibody (Active Motif,
330
Carlsbad, CA) diluted in buffer containing bovine serum albumin (1%). Subsequently,
331
the sections were incubated with biotinylated goat anti-rabbit IgG (1:100) antibody and
15
332
ExtrAvidin-Peroxidase (1:100) for 1 h each. Immunosignals were visualized using
333
diaminobenzidine. For immunostaining of TET2, we used rabbit polyclonal anti-TET2
334
(1:500, Abcam, Cambridge, UK) antibody as a primary antibody, and the immunostaining
335
was performed as described above, except for eliminating the formamide, SSC, HCl, and
336
boric acid steps.
337
For the quantification of 5-mC and 5-hmC signals, optical densities of each signal were
338
analyzed using ImageJ. Two sections from each animal were selected for hippocampus
339
and OB and the optical densities in the DG, CA1, CA3, and OB were analyzed. In each
340
section, background values obtained from adjacent brain areas were measured and
341
subtracted from the values of target areas. The signal levels measured in two sections
342
were averaged for each animal, and expressed as the percentage of the maximum value
343
of all animals.
344 345
4.4.
Statistics
346
Data were analyzed by two-way ANOVA designating photoperiod and age as the two
347
factors. When significant interaction between photoperiod and age was detected, post hoc
348
analysis was performed using Bonferroni’s multiple comparison test. Correlation analysis
349
between TET2 and 5-hmC levels was performed using Pearson’s correlation coefficient
350
with Fisher’s z transformation. Values were considered significantly different at p < 0.05.
351
For the in situ hybridization data, P4, P7, and P10 mice were analyzed separately from
352
P21 mice, because their sampling methods were different (with or without skull). t-Test
353
was used to analyze the data in the P21 mice. All analyses were performed using
354
Graphpad Prism version 7.02 for Windows (GraphPad Software Inc., San Diego, CA).
16
355
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530
Figure legends
531
Figure 1
532
Effect of postnatal photoperiod on the expression of DNA methyltransferases (DNMTs)
533
in the mouse hippocampus (HC) and olfactory bulb (OB). (A) Representative
534
autoradiographs of in situ hybridizations for DNMT1 and DNMT3a in postnatal day 4
535
(P4), P7, and P10 mice. (B) Temporal expressions of DNMT1 and DNMT3a mRNAs in
536
the hippocampal dentate gyrus (DG), CA1, CA3, and in the OB of mice postnatally
537
exposed to short-day (SD) and long-day (LD) conditions. Means ± standard error of mean
538
(n = 3 - 4). *p < 0.05, **p < 0.01, two-way ANOVA. Scale bars: 1 mm.
539 540
Figure 2
541
Effect of postnatal photoperiod on 5-methylcytosine (5-mC) levels in the mouse
542
hippocampal dentate gyrus (DG) and olfactory bulb (OB) at postnatal day 4 (P4) and P10.
543
(A) Representative images of immunostainings against 5-mC. (B) Temporal changes in
544
5-mC levels in the DG and OB in mice postnatally exposed to short-day (SD) and long-
545
day (LD) conditions. Means ± standard error of mean (n = 5 - 6). *p < 0.05, two-way
546
ANOVA. Scale bars: 50 μm.
547 548
Figure 3
549
Effect of postnatal photoperiod on 5-hydroxymethylcytosine (5-hmC) and protein levels
550
of ten-eleven translocation (TET) 2 in the hippocampus (HC) and olfactory bulb (OB) of
551
postnatal day 4 (P4), P10, and P21 mice. (A) Representative images of immunostainings
552
against 5-hmC and TET2. (B) Temporal changes in 5-hmC levels and TET2 protein levels
553
in the hippocampal dentate gyrus (DG), CA1, and CA3 and in the OB in mice postnatally
25
554
exposed to short-day (SD) and long-day (LD) conditions. The relationship between 5-
555
hmC and TET2 levels is also illustrated. Means ± standard error of mean (n = 5 - 6). *p
556
< 0.05, **p < 0.01, two-way ANOVA. #p < 0.05, ##p < 0.01, Bonferroni’s multiple
557
comparison test. Scale bars: 100 μm.
558
Postnatal photoperiod altered DNA methylation system in mouse brain.
559
Hippocampus and olfactory bulb showed different dynamics of related enzyme levels.
560
These changes may relate to long-term effects on neurogenesis and behaviors.
561
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S0006-8993(20)30081-0 https://doi.org/10.1016/j.brainres.2020.146725 BRES 146725
To appear in:
Brain Research
Received Date: Revised Date: Accepted Date:
20 January 2019 26 October 2019 10 February 2020
Please cite this article as: N. Takaki, T. Uchiwa, M. Furuse, S. Yasuo, Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain, Brain Research (2020), doi: https://doi.org/10.1016/j.brainres. 2020.146725
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1
Effect of postnatal photoperiod on DNA methylation dynamics in the mouse brain
2 3
Nozomu Takaki, Tatsuhiro Uchiwa, Mitsuhiro Furuse, Shinobu Yasuo
4 5
Laboratory of Regulation in Metabolism and Behavior, Faculty of Agriculture, Kyushu
6
University, 744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan
7 8
Corresponding author: Shinobu Yasuo, Ph.D.
9
Laboratory of Regulation in Metabolism and Behavior, Faculty of Agriculture, Kyushu-
10
University
11
744 Motooka, Nishi-ku, Fukuoka 819-0395, Japan
12
Phone/Fax: +81-92-802-4597
13
E-mail: [email protected]
14 15
Abbreviations: 5-hmC, 5-hydroxymethylcytosine; 5-mC, 5-methylcytosine; DG, dentate
16
gyrus; DNMT, DNA methyltransferase; HC, hippocampus; LD, long-day; OB, olfactory
17
bulb; P, postnatal days; SD, short-day; SSC, saline sodium citrate; TET, ten-eleven
18
translocation; ZT, Zeitgeber time.
1
19
Abstract
20
Season of birth influences the onset of psychiatric diseases in mammals. Recent studies
21
using rodent models have revealed that photoperiod during early life stages has a strong
22
impact on affective and cognitive behaviors, neuronal activity, and hippocampal
23
neurogenesis/astrogenesis in later life. The present study examined the effect of postnatal
24
photoperiod on global DNA methylation and hydroxymethylation dynamics in the mouse
25
brain. Male mice born under short-day (SD) conditions were divided into SD and long-
26
day (LD) groups on the day of birth. Temporal expression of DNA methyltransferases
27
(DNMT1/3a) with 5-methylcytosine (5-mC) levels, as well as protein levels of ten-eleven
28
translocation (TET) 2 with 5-hydroxymethylcytosine (5-hmC) levels, were analyzed from
29
postnatal day 4 (P4) to P21. Levels of 5-hmC in all hippocampal areas were higher in the
30
LD group than in the SD group at P21, with a positive correlation between 5-hmC levels
31
and TET2 levels throughout the experimental period. Inconsistent results were observed
32
between DNMT1/3a mRNA levels and 5-mC levels. On the other hand, in the OB, mRNA
33
levels of DNMT1 and DNMT3a were slightly lower in the LD group similar to 5-mC
34
levels, but TET2 and 5-hmC levels were not influenced by the photoperiod. In conclusion,
35
postnatal exposure of mice to LD conditions induces an increase in TET2-dependent
36
DNA hydroxymethylation in the hippocampus, which might be involved in the long-term
37
effects of postnatal photoperiod on neurogenesis and affective/cognitive behaviors.
38 39
Keywords: DNA methyltransferase; Ten-eleven translocation; Hippocampus; 5-
40
Methylcytosine; 5-Hydroxymethylcytosine
2
41
1. Introduction
42
Seasonal changes in photoperiod influence various physiological functions and
43
behaviors in mammals, including reproduction, energy homeostasis, neuroplasticity, and
44
affective/cognitive behaviors (Dardente et al., 2019; Prendergast and Nelson, 2005;
45
Walton et al., 2011). In addition, gestational and/or postnatal photoperiod has enduring
46
effects on physiological and behavioral phenotypes; pre- and/or postnatal exposure to
47
short-day (SD) condition increases anxiety- and/or depression-like behaviors in Siberian
48
hamsters (Pyter and Nelson, 2006), rats (Toki et al., 2007), and C3H mice (Green et al.,
49
2015). Our previous studies demonstrated that C57BL/6J mice are a useful strain for the
50
study of photoperiodic regulation in affective behaviors, evidenced by the photoperiodic
51
changes in depression-like behaviors and related functions (Otsuka et al., 2012; Otsuka
52
et al., 2014). We have further clarified that photoperiod during early life stages altered
53
prepulse inhibition and depression-like behavior in adult C57BL/6J mice (Takai et al.,
54
2018). The critical window in rodents appears to be the early postnatal period (Takai et
55
al., 2018; Uchiwa et al., 2016), which is equivalent to the third trimester of pregnancy in
56
humans in terms of brain development (Clancy et al., 2007). The hippocampus represents
57
one of the photoperiod-programmable regions, given that pre- and postnatal photoperiod
58
alter the proliferation of neural stem cells and astrogenesis in the dentate gyrus (DG), as
59
well as expression of glucocorticoid receptors in later life (Takai et al., 2018; Toki et al.,
60
2007). These reports suggest that epigenetic mechanisms are involved in the long-term
61
effect of photoperiod over life stages, which may be related to the association between
62
birth season and the onset of psychiatric diseases, including schizophrenia, bipolar
63
disorder, and seasonal affective disorder in humans (Foster and Roenneberg, 2008).
64
DNA methylation is one of the major epigenetic modification systems and has
3
65
important roles in neurodevelopmental or psychiatric diseases. For example, inhibition of
66
DNA methylation in the hippocampus demonstrated anti-depressant-like effects (Sales et
67
al., 2011), and DNA methylation on peripheral blood DNA was associated with traits of
68
autism (Wong et al., 2014), and schizophrenia (Dempster et al., 2011). DNA methylation
69
occurs by the addition of a methyl group to C5 position of cytosine to form 5-
70
methylcytosine (5-mC), catalyzed by a family of DNA methyltransferases (DNMTs). De
71
novo methylation is catalyzed by DNMT3a and DNMT3b, while DNMT1 maintains the
72
pattern of methylation when DNA duplicates (Johnson et al., 2012). Alternately, ten-
73
eleven translocation (TET) proteins (TET1, TET2, and TET3) are involved in the DNA
74
demethylation
75
hydroxymethylcytosine (5-hmC), 5-formylcytosine and 5-carboxylcytosine (Wu and
76
Zhang, 2017). Approximately 60 - 80% of CpG sites in the mammalian genome are
77
modified to 5-mC, and 5-hmC accounting for roughly 40% of the modified cytosine in
78
the brain (Kriaucionis and Heintz, 2009; Smith and Meissner, 2013). Methylation of CpG
79
islands plays a role in silencing of transcription and heterochromatin formation (Smith
80
and Meissner, 2013). Recent studies further clarified that 5-hmC is not only an
81
intermediate of demethylation process, but also has specific functions, such as promotion
82
of transcription and chromatin accessibility via a 5-hmC-binding protein (Mellén et al.,
83
2012). Epigenetic modification by 5-hmC is associated with neurodevelopment and
84
diseases; 5-hmC levels in the hippocampus are decreased in patients with Alzheimer's
85
disease (Chouliaras et al., 2013), and 5-hmC levels in the cerebellum are inversely
86
correlated with the levels of methyl-CpG-binding protein 2, a protein responsible for Rett
87
syndrome (Szulwach et al., 2011).
88
process,
catalyzing
the
conversion
from
5-mC
into
5-
Developmental changes in the expression of DNMTs in the brain have been reported
4
89
in rats. The expression levels of DNMTs were highest during the first week of life and
90
decreased gradually until 3 weeks postnatally, although global DNA methylation levels
91
did not follow this expression pattern (Simmons et al., 2013). It was also reported that
92
neuronal cells in mice acquire 5-hmC from postnatal neurodevelopment through
93
adulthood (Szulwach et al., 2011). Environmental factors such as caregiver maltreatment
94
and dietary conditions alter 5-mC and 5-hmC levels in the hippocampus, amygdala, or
95
thalamus (Doherty et al., 2016; Weng et al., 2014) suggesting that DNA methylation
96
dynamics may be additionally modified by early postnatal photoperiod. Therefore, in this
97
study we analyzed the effect of early postnatal photoperiod on the mRNA or protein levels
98
of DNMTs and TETs, as well as global 5-mC and 5-hmC levels in the C57BL/6J mouse
99
brain. For the analysis of TETs, we focused on TET2 due to the strong impact of TET2
100
in neurogenesis and memory (Gontier et al., 2018).
5
101
2. Results
102
2.1.
The mRNA expression of DNMT1 and DNMT3a
103
Expressions of both DNMT1 and DNMT3a were most prominent in the hippocampus
104
and olfactory bulb (OB) as observed by in situ hybridization (Fig. 1A). Therefore, we
105
measured their mRNA levels in these particular regions. Overall, the mRNA levels of
106
DNMT1 in the hippocampus and OB were lower in the long-day (LD) group compared
107
with its levels in the SD group (Fig. 1B). A statistically significant difference was detected
108
in the OB (F(1,17)=13.73, p < 0.01), and a trend was observed in the DG (F(1,17)=4.42,
109
p = 0.0506). Moreover, the effect of age was significant in all regions (DG: F(2,17)=6.42,
110
CA1: F(2,16)=10.83, OB: F(2,17)=8.83, p < 0.01, CA3: F(2,16)=5.62, p < 0.05); the
111
mRNA levels of DNMT1 decreased with increasing age (Fig. 1B). No significant
112
interaction between photoperiod and age was detected in any of the regions examined.
113
The mRNA levels of DNMT3a in the hippocampus and OB were also lower in LD group
114
compared with its levels in the SD group (Fig. 1B). The main effect of photoperiod was
115
detected in the CA3 (F(1,17)=11.00, p < 0.01) and OB (F(1,17)=6.74, p < 0.05). However,
116
neither the effect of age nor the interaction between photoperiod and age were significant
117
in any of the regions analyzed. The mRNA levels of neither DNMT1 nor DNMT3a in the
118
hippocampus and OB in the 21-day-old (P21) mice were affected by the photoperiod (data
119
not shown).
120 121
2.2.
Global levels of 5-mC and 5-hmC
122
5-mC was clearly detected by immunostaining in the DG and OB of P4 and P10 mice.
123
However, in CA1 and CA3 at the same ages, 5-mC levels were too weak to analyze (Fig.
124
2A). Moreover, weak 5-mC signals were observed in the brains of P21 mice (data not
6
125
shown). Therefore, we quantified 5-mC signals only in the DG and OB of P4 and P10
126
mice. Our results demonstrated that there was no significant difference in 5-mC levels in
127
the DG between mice of the LD and SD group (Fig. 2B). However, 5-mC levels in the
128
OB were significantly lower in the mice under LD condition compared with those under
129
SD (F(1,19)=4.92, p < 0.05, Fig. 2B). Additionally, the effect of age on 5-mC levels was
130
significant in the DG (F(1,19)=6.24, p < 0.05), but not in the OB. No significant
131
interaction was detected between photoperiod and age.
132
Further, 5-hmC was clearly detected by immunostaining in the hippocampus and OB
133
of P4, P10, and P21 mice (Fig. 3A). 5-hmC levels in the DG and CA3 were not
134
significantly different between LD and SD groups, while those in CA1 were significantly
135
higher in the LD group compared with those in the SD group (F(1,28) =6.28, p < 0.05,
136
Fig. 3B). Post-hoc analysis clarified that 5-hmC levels in the LD group were significantly
137
higher compared with those in the SD group in all hippocampal regions of P21 mice (p <
138
0.01; Fig. 3B). Moreover, the effect of age on 5-hmC levels was significant in all
139
hippocampal regions (DG: F(2,29)=11.32, CA1: F(2,28)=40.67, CA3: F(2,29)=60.49, p
140
< 0.001); 5-hmC levels decreased with increasing age in the hippocampus, whereas they
141
increased with increasing age in the OB (Fig. 3B). Furthermore, significant interactions
142
between photoperiod and age were detected in all hippocampal regions (DG:
143
F(2,29)=6.31, CA3: F(2,29)=8.43, p < 0.01; CA1: F(2,28)=4.63, p < 0.05). The levels of
144
5-hmC in the OB were not significantly different between LD and SD groups at any age
145
(Fig. 3B).
146 147 148
2.3.
TET2 protein levels
TET2 immunosignals were clearly detected in the hippocampus and OB (Fig. 3A).
7
149
Signals in all regions were not significantly different between LD and SD groups (Fig.
150
3B). The main effect of age on TET2 levels was significant in all brain regions examined
151
(DG: F(2,28)=17.59, CA1: F(2,27)=46.51, CA3: F(2,29)=62.71, p < 0.001; OB:
152
F(2,30)=3.60, p < 0.05). Similar to 5-hmC levels, TET2 levels decreased or increased
153
with increasing age in the hippocampus and OB, respectively (Fig. 3B). A statistically
154
significant interaction between photoperiod and age was detected in all hippocampal
155
regions (DG: F(2,28)=4.22, CA1: F(2,27)=4.97, p < 0.05; CA3: F(2,29)=7.62, p < 0.01).
156
Post-hoc analysis demonstrated that TET2 levels were significantly lower in the LD group
157
compared with those in the SD group in the DG and CA3 of P4 mice (DG: p < 0.05, CA3:
158
p < 0.01).
159
The photoperiod- and age-dependent trends were similar for 5-hmC and TET2 levels;
160
therefore, we sought to analyze the correlation between them. Indeed, we found strong
161
correlations between TET2 and 5-hmC levels in the DG (p < 0.0001, r = 0.709, Fig. 3B),
162
CA1 (p < 0.0001, r = 0.892, Fig. 3B), and CA3 (p < 0.0001, r = 0.938, Fig. 3B). On the
163
other hand, the correlation between TET2 levels and 5-hmC levels in the OB was rather
164
weak (p < 0.05, r = 0.403, Fig. 3B).
8
165
3. Discussion
166
The present study demonstrated, for the first time, that early postnatal photoperiod
167
alters DNA methylation and hydroxymethylation dynamics in the hippocampus and OB
168
in a region-specific manner. Furthermore, exposure of mice to LD conditions induces an
169
increase in the DNA hydroxymethylation marker (5-hmC) in the hippocampus and a
170
decrease in the DNA methylation marker (5-mC) in the OB. Importantly, these changes
171
reflect the changes in the mRNA expression or protein levels of regulatory enzymes.
172
Hippocampal TET2 and 5-hmC levels showed a positive correlation, as observed in the
173
comparison between young and aged mice (Gontier et al., 2018) and the promotor region
174
of miR-137 between sedentary and exercise groups in aged mice (Jessop and Toledo-
175
Rodriguez, 2018). In the OB, the mRNA levels of DNMT1 and DNMT3a were lower in
176
the LD group, similar to that of 5-mC levels, although the physiological consequences
177
remain unclear. DNA methylation status in the OB is linked to odor location memories
178
in injured mice (Tajerian et al., 2019), suggesting a modulatory role of postnatal
179
photoperiod in sensory systems.
180
A previous study reported that exposure of adult animals to different photoperiods
181
alters DNMTs expression in Siberian hamsters, in which DNMT3a expression in the
182
hypothalamus was higher in hamsters under LD condition than in those under SD
183
(Stevenson, 2017). Another study using adult male and female Siberian hamsters
184
demonstrated that DNMT3a expression in the testis and uterus was higher in animals
185
exposed to SD than in those exposed to LD, with higher global 5-mC levels in the testis
186
(Lynch et al., 2016). The present study is the first to demonstrate the effect of early
187
postnatal photoperiod on DNA methylation/hydroxymethylation associated measures,
188
including DNMTs expression. Furthermore, the results observed in the hippocampus and
9
189
OB were different from those of other tissues in animals exposed to photoperiods during
190
adulthood. Taken together, the effect of photoperiod on the expression of DNMTs and 5-
191
mC levels appears to be brain-region specific and, on the other hand, to depend on the
192
organ, age, and sex examined in each study.
193
The physiological impact of the early postnatal photoperiod-dependent modulation of
194
DNA methylation/hydroxymethylation is not clear in the present study. One possible
195
explanation is the influence on hippocampal neurogenesis and related behaviors in later
196
life, which have been shown to be modulated by early postnatal photoperiod in mice, rats,
197
and hamsters (Green et al., 2015; Pyter and Nelson, 2006; Takai et al., 2018; Toki et al.,
198
2007). Deficiency of dietary methyl-donors in adolescence resulted in impaired learning
199
and memory, and decreased expression of glutamate receptors with specific CpG
200
hypermethylation (Tomizawa et al., 2015). In adult rats bred for low response to novelty,
201
increased dietary methyl-donor content ameliorated anxiety-like behaviors and decreased
202
immobility in the forced swim test (McCoy et al., 2017). In addition, 5-hmC abundance
203
increased with neural stem cell differentiation, accompanied by increased TET2 protein
204
levels (Li et al., 2017). Thus, age-dependent changes in TET2 and 5-hmC levels in the
205
hippocampus are positively associated with neurogenesis and cognitive functions
206
(Gontier et al., 2018; Jessop and Toledo-Rodriguez, 2018). Notably, the present study
207
clarified higher levels of 5-hmC and TET2 in the hippocampus of the LD group,
208
compared with those in the SD group, which is in agreement with the higher levels of
209
neurogenesis in animals bred under LD (Takai et al., 2018). Mechanisms underlying
210
postnatal photoperiod-induced changes in 5-hmC/TET2 levels remain unclear. TET2
211
proteins can be regulated by calpains, a family of calcium-dependent proteases (Wang
212
and Zhang, 278). Calpain activity in hippocampal cells is modulated by glucocorticoid
10
213
and retinoic acid signaling (Roumes et al., 2016), both which are under the control of
214
photoperiod (Otsuka et al., 2012; Dardente et al., 2019), suggesting a possible role in the
215
regulation of TET2 protein levels.
216
One of the cellular functions of DNA methylation/hydroxymethylation system is
217
transcriptional regulation. At the molecular level, our previous study showed that early
218
postnatal photoperiod alters the expression of a glucocorticoid receptor (Nr3c1) in the
219
hippocampus (Takai et al., 2018). The present study revealed that postnatal photoperiod
220
induced changes in DNA hydroxymethylation in the hippocampus. These data suggest
221
that
222
methylation/hydroxymethylation dynamics as a consequence of photoperiodic conditions,
223
given that DNA methylation of Nr3c1 is highly sensitive to stress and glucocorticoid, a
224
photoperiod-controlled hormone (Otsuka et al., 2012). For example, repetitive restrain
225
stress on rats decreased global methylation levels in the hippocampus with decreased
226
expression of Nr3c1 (Makhathini et al., 2017), and acute stress increased 5-hmC levels
227
of Nr3c1 promoter in the mouse hippocampus (Li et al., 2015). Embryonic exposure to
228
high dose of corticosterone increased DNA methylation of the hypothalamic Nr3c1 gene
229
in the chicken (Ahmed et al., 2014). However, we have no data about the effect of early
230
postnatal photoperiod on methylation/hypermethylation levels in specific genes, nor
231
genomic distribution of their markers, which needs to be studied in future.
the
altered
expression
of
Nr3c1
may
be
caused
by
DNA
232
In the present study, expression of DNMT1 and DNMT3a and 5-mC levels in both the
233
hippocampus and OB decreased with age. These observations are in congruence with the
234
report using rats, in which expression of DNMTs and 5-mC levels gradually decreased
235
from birth to P21 in the hippocampus (Simmons et al., 2013). The present study also
236
showed an age-dependent decrease in 5-hmC and TET2 protein levels in the hippocampus,
11
237
in line with findings of a previous study, showing that 5-hmC and TET2 levels decreased
238
with age, at least until the age of 18 months, and affected neurogenesis and memory in
239
mice (Gontier et al., 2018). On the other hand, we uncovered unexpected results in the
240
OB, in which 5-hmC and TET2 levels increased with age. Brain area-specific patterns of
241
age-dependent 5-hmC and TET2 levels may be related with different timing of postnatal
242
synaptogenesis and neurogenesis between the hippocampus and the OB; synaptogenesis
243
and neurogenesis in the DG is most active between P7 and P30 (O'Kusky et al., 2000;
244
Steward and Falk, 1986), while the OB grows steadily in size from birth to maturity, until
245
the age of 12 weeks (Pomeroy et al., 1990).
246
In conclusion, here we demonstrated that the photoperiod during early postnatal life
247
differentially alters DNA methylation and hydroxymethylation systems in the mouse
248
hippocampus and OB. In the hippocampus, the photoperiod possibly alters global 5-hmC
249
levels by modulating TET2 protein levels. In the OB, global 5-mC levels were regulated
250
by the photoperiod and similar changes were observed in the expression of DNMTs.
251
These changes may have long-term effects on neurogenesis and affective/cognitive
252
behaviors.
253 254
Conflict of interest
255
The authors declare that they have no conflict of interest.
256 257
Acknowledgement
258
This study was supported by Grants-in-Aid for Challenging Exploratory Research
259
(No.17K19914) to S.Y. from the Japanese Society for the Promotion of Science.
12
260
4. Experimental procedure
261
4.1.
Animals
262
The study was conducted according to the Guidelines for Animal Experiments by the
263
Faculty of Agriculture in Kyushu University, following the law No. 105 and Notification
264
No. 6. All animal experiments reported here were conducted in accordance with the as
265
well as All experiments were approved by Animal Care and Use Committee of Kyushu
266
University (A28-069-0). Mice were maintained in a light-tight box placed in a room at
267
the temperature of 25 ± 1°C. Water and standard diet for laboratory rodents (MF, Oriental
268
Yeast, Tokyo, Japan) were available ad libitum and were replenished at least once a week.
269
Male and female 6-week-old C57BL/6J mice obtained from Japan SLC, Inc. were
270
separately housed in groups of 3 or 4 animals under SD (6 h light - 18 h dark, 6L18D) for
271
more than 3 weeks. Thereafter they were mated under SD and the offsprings with their
272
mothers and littermates were randomly separated into 2 groups on the day of birth: SD
273
and LD (18 h light - 6 h dark, 18L6D) groups. Both groups included offsprings from 2 -
274
4 litters in each age. This study used the SD condition, not 12L12D, for acclimation and
275
control for the following reasons: 1) the shifts from 12L12D to SD and from 12L12D to
276
LD are opposite to each other with regard to the photoperiodic response and have been
277
suggested to involve distinct mechanisms; thus, it would be difficult to compare the
278
outcomes (Yasuo et al., 2010); 2) 12L12D was interpreted as a stimulatory LD condition
279
in F344 rats (Tavolaro et al., 2015) and, thus, the effect of LD would not be precisely
280
evaluated. Therefore, we used SD as the control condition and focused on the stimulatory
281
effect of LD.
282
For in situ hybridization, the offsprings at P4, P7, P10 and P21 (n = 3 - 4, including
283
offsprings from more than 2 litters for each age) were euthanized by isoflurane gas and
13
284
decapitated at Zeitgeber time (ZT; ZT0 corresponds to light onset) 2. The brains were
285
collected and frozen with dry ice and stored in -80 °C until analysis. Because it was
286
difficult to quickly remove the skull of P4, P7, and P10 mice, their brains were frozen
287
with the skull. For immunohistochemistry, the offsprings at P4, P10 and P21 (n = 5 - 6,
288
including offsprings from more than 2 litters for each age) were euthanized by isoflurane
289
gas and decapitated at ZT2, and the brains were incubated with 4% paraformaldehyde for
290
12 h and cryoprotected with 20% sucrose at 4 °C. The brains were embedded in OCT
291
compound and frozen quickly. For both analyses, only male offsprings were used because
292
it is reported that the effect of early postnatal environment on DNA methylation in the
293
hippocampus is different between male and female rats (Doherty et al., 2016), and in the
294
previous studies on the effect of postnatal photoperiod male animals were often used
295
(Takai et al., 2018; Toki et al., 2007; Uchiwa et al., 2016). Therefore, the results of the
296
present and previous studies can be compared appropriately.
297 298
4.2.
In situ hybridization
299
Sagittal brain sections (18 μm-thick) were prepared using a cryostat (Leica, Wetzler,
300
Germany). Antisense and sense oligonucleotide probes for each gene (antisense: DNMT1:
301
5′-GGCCCACAGCGTTTCCGAGATGCCTGCTTGGTGGAATCCTTCCGA-3′;
302
DNMT3a:
303
GCCTCCAATGAAGAGTGGGTGCTCCAGGGTGACATTGAGGCTCCC-3′)
304
labeled with [33P]dATP (PerkinElmer, MA, US) by using terminal deoxynucleotidyl
305
transferase (Invitrogen, CA, US) at 37 °C for 2 h. The sections were fixed using 4%
306
paraformaldehyde in phosphate buffered saline for 10 min, and hybridization was carried
307
out overnight at 42 °C with 750,000 cpm of 33P-labeled probe for each slide. Two high-
5′-
14
were
308
stringency post-hybridization washes were performed at 55 °C. The sections were air-
309
dried and exposed to an X-ray film (Kodak, Tokyo, Japan) for 2 weeks with 14C-labeled
310
standards (American Radiolabeled Chemicals, MO, US). Sense probes detected no
311
signals for either DNMT1 or DNMT3a. We also performed the analysis for DNMT3b and
312
TET2 expression, but signals were too weak to analyze (data not shown).
313
Relative optical densities of signals were measured using a computed image analysis
314
system (ImageJ, National Institutes of Health, http://imagej.nih.gov/ij) and were
315
converted into the relative radioactivity units (Bq/mg) by using the 14C-labeled standards.
316
Two sections including the hippocampus and OB were selected from each animal for each
317
gene, and signals in the DG, CA1, CA3, and OB were analyzed. In each section,
318
background values obtained from adjacent brain areas that did not exhibit a hybridization
319
signal were subtracted. Signals from two sections were averaged in each animal.
320 321
4.3.
Immunohistochemistry
322
Sagittal cryostat sections (20 μm-thick) including the hippocampus and OB were
323
prepared. For immunostaining of 5-mC and 5-hmC, the sections were dried and soaked
324
sequentially in 1.5% hydrogen peroxide in methanol for 10 min, 50% formamide/2 ×
325
saline sodium citrate (SSC) at 65 °C for 30 min, 2 × SSC for 5 min, 1 N hydrochloric acid
326
at 37 °C for 30 min, and 0.1 M boric acid (pH 8.5) for 10 min. The sections were then
327
incubated with 10% normal goat serum for 30 min. Thereafter, the sections were
328
incubated overnight with rabbit monoclonal anti-5-mC antibody (1:800, Cell Signaling
329
Technology, Danvers, MA) or rabbit polyclonal anti-5-hmC antibody (Active Motif,
330
Carlsbad, CA) diluted in buffer containing bovine serum albumin (1%). Subsequently,
331
the sections were incubated with biotinylated goat anti-rabbit IgG (1:100) antibody and
15
332
ExtrAvidin-Peroxidase (1:100) for 1 h each. Immunosignals were visualized using
333
diaminobenzidine. For immunostaining of TET2, we used rabbit polyclonal anti-TET2
334
(1:500, Abcam, Cambridge, UK) antibody as a primary antibody, and the immunostaining
335
was performed as described above, except for eliminating the formamide, SSC, HCl, and
336
boric acid steps.
337
For the quantification of 5-mC and 5-hmC signals, optical densities of each signal were
338
analyzed using ImageJ. Two sections from each animal were selected for hippocampus
339
and OB and the optical densities in the DG, CA1, CA3, and OB were analyzed. In each
340
section, background values obtained from adjacent brain areas were measured and
341
subtracted from the values of target areas. The signal levels measured in two sections
342
were averaged for each animal, and expressed as the percentage of the maximum value
343
of all animals.
344 345
4.4.
Statistics
346
Data were analyzed by two-way ANOVA designating photoperiod and age as the two
347
factors. When significant interaction between photoperiod and age was detected, post hoc
348
analysis was performed using Bonferroni’s multiple comparison test. Correlation analysis
349
between TET2 and 5-hmC levels was performed using Pearson’s correlation coefficient
350
with Fisher’s z transformation. Values were considered significantly different at p < 0.05.
351
For the in situ hybridization data, P4, P7, and P10 mice were analyzed separately from
352
P21 mice, because their sampling methods were different (with or without skull). t-Test
353
was used to analyze the data in the P21 mice. All analyses were performed using
354
Graphpad Prism version 7.02 for Windows (GraphPad Software Inc., San Diego, CA).
16
355
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Figure legends
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Figure 1
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Effect of postnatal photoperiod on the expression of DNA methyltransferases (DNMTs)
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in the mouse hippocampus (HC) and olfactory bulb (OB). (A) Representative
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autoradiographs of in situ hybridizations for DNMT1 and DNMT3a in postnatal day 4
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(P4), P7, and P10 mice. (B) Temporal expressions of DNMT1 and DNMT3a mRNAs in
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the hippocampal dentate gyrus (DG), CA1, CA3, and in the OB of mice postnatally
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exposed to short-day (SD) and long-day (LD) conditions. Means ± standard error of mean
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(n = 3 - 4). *p < 0.05, **p < 0.01, two-way ANOVA. Scale bars: 1 mm.
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Figure 2
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Effect of postnatal photoperiod on 5-methylcytosine (5-mC) levels in the mouse
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hippocampal dentate gyrus (DG) and olfactory bulb (OB) at postnatal day 4 (P4) and P10.
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(A) Representative images of immunostainings against 5-mC. (B) Temporal changes in
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5-mC levels in the DG and OB in mice postnatally exposed to short-day (SD) and long-
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day (LD) conditions. Means ± standard error of mean (n = 5 - 6). *p < 0.05, two-way
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ANOVA. Scale bars: 50 μm.
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Figure 3
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Effect of postnatal photoperiod on 5-hydroxymethylcytosine (5-hmC) and protein levels
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of ten-eleven translocation (TET) 2 in the hippocampus (HC) and olfactory bulb (OB) of
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postnatal day 4 (P4), P10, and P21 mice. (A) Representative images of immunostainings
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against 5-hmC and TET2. (B) Temporal changes in 5-hmC levels and TET2 protein levels
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in the hippocampal dentate gyrus (DG), CA1, and CA3 and in the OB in mice postnatally
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exposed to short-day (SD) and long-day (LD) conditions. The relationship between 5-
555
hmC and TET2 levels is also illustrated. Means ± standard error of mean (n = 5 - 6). *p
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< 0.05, **p < 0.01, two-way ANOVA. #p < 0.05, ##p < 0.01, Bonferroni’s multiple
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comparison test. Scale bars: 100 μm.
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Postnatal photoperiod altered DNA methylation system in mouse brain.
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Hippocampus and olfactory bulb showed different dynamics of related enzyme levels.
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These changes may relate to long-term effects on neurogenesis and behaviors.
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