(Received for publication, April 21, 1997, and in revised form, June 12, 1997)
From the Department of Development and Genetics, the Babraham Institute, Cambridge CB2 4AT, United Kingdom and the § Department of Cell Biology, University of the Basque Country, 48940 Leioa, Spain
The imprinted U2af1-rs1 gene on mouse
chromosome 11 is expressed exclusively from the paternal allele. We
found that U2af1-rs1 resides in a chromosomal domain that
displays marked differences in chromatin conformation and DNA
methylation between the parental chromosomes. Chromatin conformation
was assayed in brain and liver, in fetuses, and in embryonic stem cells
by sensitivity to nucleases in nuclei. In all these tissues, the
unmethylated paternal chromosome is sensitive to DNase-I and
MspI and has two DNase-I hypersensitive sites in the
5-untranslated region. In brain and in differentiated stem cells,
which display high levels of U2af1-rs1 expression, a
paternal DNase-I hypersensitive site is also readily apparent in the
promoter region. On the maternal chromosome, in contrast, the entire
U2af1-rs1 gene and its promoter are highly resistant to
DNase-I and MspI in all tissues analyzed and are fully
methylated. No differential MNase sensitivity was detected in this
imprinted domain. The parental chromosome-specific DNA methylation and
chromatin conformation were also present in parthenogenetic and
androgenetic cells and in tissues from animals maternally or paternally
disomic for chromosome 11. This demonstrates that these parental
chromosome-specific epigenotypes are independently established and
maintained and provides no evidence for interallelic
trans-sensing and counting mechanisms in
U2af1-rs1.
Parental imprinting is an epigenetic mechanism in mammals that gives rise to differential expression of the maternally and paternally inherited alleles of certain genes. The identification of the epigenetic modifications (imprints) responsible for parental allele-specific expression has gained considerable impetus since the discovery of the first imprinted genes, and it is generally assumed that primary modifications are established in the germline or prior to syngamy after fertilization (1, 2). CpG methylation is an epigenetic modification of DNA that has been found to correlate with the allelic expression of imprinted genes (3). In several imprinted genes, such as H19, SNRPN, and U2af1-rs1 (4-8), DNA sequences involved in expression are methylated specifically on the repressed allele, which suggests that allelic methylation represses transcription. In contrast, there are other imprinted genes in which small intragenic regions are methylated exclusively on the expressed allele. These include Igf2 (9) and Igf2r (10), and methylation in these genes may be involved in activation of transcription. Imprinting studies in DNA methyltransferase-deficient mice have shown that DNA methylation is clearly required for at least the somatic maintenance of monoallelic expression (11, 12). In the imprinted genes analyzed so far, with the possible exception of a region upstream of H19 (13) and "region 2" of Igf2r (10), the allelic methylation patterns seem, however, to arise after fertilization, during early development (14-16). They would therefore not necessarily constitute primary imprints and may reflect other, pre-existing epigenetic features of chromatin.
It has been found that autosomal imprinted gene regions replicate earlier on the paternal than on the maternal chromosome during S phase (17, 18). Earlier studies had established asynchrony of replication of genes on the differentially compacted, active, and inactive X chromosome in female mammals (19). The asynchronous replication of imprinted and X-linked genes suggests that differential chromatin compaction may be another characteristic of mono-allelically expressed genes. For the imprinted Igf2/H19 domain on mouse distal chromosome 7, this has been studied more directly by our laboratory and by others in assays that analyze allelic sensitivity to nucleases in nuclei. No parental chromosome-specific chromatin conformation was thus detected in the Igf2 gene, including its promoters (20, 21), and in the body of the H19 gene. Both regions were equally sensitive to DNase-I on the maternal and the paternal chromosome, and the same was found for the 90-kb1 region between the two genes (22). However, the H19 promoter was found to be more sensitive to nucleases on the expressed maternal than on the repressed paternal chromosome (4). This finding suggests chromosome-specific chromatin compaction in the regulatory sequences of H19, which could be associated with the allelic expression of this imprinted gene.
To gain more insight into the role of chromatin in the regulation of
imprinting, we analyzed allelic chromatin conformation in the imprinted
mouse U2af1-rs1 gene. U2af1-rs1 (named SP2 (6) or
U2afbp-rs (7) in some previous studies) is a small,
intronless gene that is paternally expressed in embryonic and adult
tissues. It codes for a protein with homology to the splicing factor U2 small nuclear ribonucleoprotein auxiliary factor (6, 7). It is the only
imprinted gene identified on mouse proximal chromosome 11, the paternal
disomy of which gives fetal overgrowth, whereas maternal disomy leads
to fetal growth retardation (23). It has been shown previously that
specific CpG dinucleotides in the promoter and in the 5-untranslated
region (UTR) of U2af1-rs1 are methylated on the repressed
maternal allele (6, 7, 24). In this study we show that, in fact, a
larger domain comprising the entire U2af1-rs1 gene becomes
completely methylated on the maternal chromosomes during early
development but remains unmethylated on paternal chromosomes. Most
interestingly and in contrast to the previous studies on the imprinted
Igf2 and H19 genes, the parental chromosomes also
showed a pronounced difference in generalized sensitivity to nucleases
in the entire U2af1-rs1 domain of differential methylation. We also characterized paternal DNase-I hypersensitive sites (HSS) in
the 5
-UTR and the promoter of the gene. These sites have been independently identified by Shibata and collegues (25) but only in a
single tissue. Our study, however, specifically addresses the nature
and the developmental regulation of differential chromatin conformation
in the U2af1-rs1 domain. It shows that the parental chromosome-specific chromatin conformation and the maternal DNA methylation in the U2af1-rs1 domain are intricately linked
and become established before implantation.
It has been proposed that intergenomic and trans-allelic interactions play a role in the mechanism of genomic imprinting (16, 26-29). Analysis of allelic expression and methylation in monoparental and uniparentally disomic cells and embryos has provided both evidence for (16, 27-29) and against (5, 9, 30-32) such "trans-sensing" mechanisms (for review see Ref. 30). For the U2af1-rs1 gene, which is paternally expressed from the two-cell stage on (24, 31), it has been found that androgenetic preimplantation embryos expressed about twice as much mRNA as normal embryos, whereas mRNA expression was much lower in gynogenetic preimplantation embryos (31). To further address a possible involvement of trans-sensing in the imprinting of U2af1-rs1, we analyzed parthenogenetic (Pg) and androgenetic (Ag) embryonic stem (ES) cells and tissues from animals uniparentally disomic for mouse proximal chromosome 11, which all showed the appropriate parental chromosome-specific DNA methylation and chromatin conformational patterns. These findings suggest that the maternal and paternal imprints in U2af1-rs1 are independently established and maintained and provide no evidence for trans-sensing in this imprinted gene.
Hybrid F1 mice were produced by crossing C57BL/6 females to Mus spretus males, and the reciprocal F2 mice were produced by backcrossing F1 females to C57BL/6 males. Mice maternally (Matdi-11) or paternally (Patdi-11) disomic for proximal chromosome 11 were produced by intercrossing mice heterozygous for the Robertsonian translocation, Rb(11.13)4Bnr (23). Pg embryos and Pg and Ag ES cells were derived as described before (32). Biparental, hybrid ES cells were derived as follows: mature (C57BL/6 × CBA/CA)F1 eggs were in vitro fertilized with M. spretus sperm, embryos were cultured in vitro to the blastocyst stage, and ES cell lines were derived subsequently as described before (32). ES cell lines were maintained on feeder cells, but for the chromatin and methylation assays, culture was performed in the absence of feeder cells, and only semiconfluent early passage (<passage 6) cells were used, which showed <10% of morphologically apparent differentiation. For in vitro differentiation, Ag and normal ES cells were seeded at low density on tissue-culture dishes and grown in ES medium without LIF. After 5 days, semi-confluently growing differentiated cells (>90%) were obtained that appeared mostly parietal endoderm in morphology (32).
Genomic Cloning of the U2af1-rs1 RegionPhage mU2D1 was
isolated from a genomic library of 129/Sv DNA (33) using a
NotI-EcoRV fragment from the plasmid pSP2 (6). Mapping of endonuclease restriction sites in this 15-kb phage (see Fig.
1) was performed by partial digestion and labeling with left arm- and
right arm-specific oligonucleotide probes.
Nuclease Sensitivity Assays
Nuclei were isolated from
tissues and ES cells as described previously (21). DNase-I assays were
described before (21), and the unit definition was as defined by the
manufacturer (Boehringer Mannheim). Micrococcal nuclease (MNase)
digestions were performed on purified nuclei for 5 min at 37 °C in
15 mM Tris-HCl, pH 7.5, 60 mM KCl, 15 mM NaCl, 0.15 mM -mercaptoethanol, 0.15 mM spermine, 0.5 mM spermidine, 0.34 M sucrose, 10 mM NaHSO3, 1 mM CaCl2. MspI digestions on nuclei
were performed at 37 °C in 50 mM Tris-HCl, pH 7.9, 10 mM MgCl2, 100 mM NaCl, 1 mM dithiothreitol. After incubation with DNase-I, MNase, or
MspI, the 200-µl reactions were terminated by the addition
of an equal volume of 20 mM EDTA, pH 8.0, 1% SDS. Proteinase-K was added to 200 µg/ml, and proteinase-K digestion was
carried out overnight at 37 °C, after which genomic DNA was extracted.
Genomic DNA extraction, endonuclease digestion, electrophoresis, and Southern blotting were performed as described before (9). C57BL/6 and M. spretus DNAs were analyzed for RFLPs between the two mouse species using the restriction endonucleases ApaI, BamHI, BglII, BsaI, DraI, EcoRI, EcoRV, HindIII, KpnI, PstI, PvuII, MspI, RsaI, SacI, StuI, XbaI, and XhoI. Densitometric measurements on x-ray films were performed with a Bio-Rad GelDoc-1000 apparatus. The allele-specific expression analysis by reverse transcription-polymerase chain reaction amplification on hybrid ES cell RNAs was performed as described by Hatada et al. (6) and M. spretus had the same polymorphic RsaI restriction site as described previously for Mus musculus molossinus (6). Northern blot analysis of total RNAs was performed as described previously (32).
We analyzed sensitivity to DNase-I in the U2af1-rs1 gene in adult liver and brain and in day 15 fetuses. Interspecific F1 hybrids between M. m. domesticus females and M. spretus males ([C57BL/6 × M. spretus] F1) and the reciprocal hybrids ([C57BL/6 × M. spretus] × C57BL/6) F2) were studied. To distinguish between the parental chromosomes in these interspecific hybrids, we used RFLPs between the two mouse species. Fig. 1 shows the chromosomal region analyzed and indicates the RFLPs and the genomic DNA probes used in this study.
Using the BglII RFLP, which has polymorphic fragments that
cover the entire gene, we found that in liver (Fig.
2A), brain (Fig.
2B), and day 15 fetuses (not shown), the paternal chromosome was more sensitive to DNase-I than the maternal chromosome. Hence, in
(M. m. domesticus × M. spretus) F1 hybrid
nuclei, the 4.3-kb paternal M. spretus restriction fragment
was sensitive to DNase-I, whereas the 5.6-kb maternal M. m.
domesticus restriction fragment was highly resistant to DNase-I.
In addition, in liver, brain, and fetuses, two paternal
chromosome-specific DNase-I HSS were detected in the 5-UTR. These
closely linked HSS mapped directly downstream of the previously
described, maternally methylated, NotI restriction site
(Refs. 6 and 7; Fig. 2A). Both for liver (Fig.
2A) and brain (not shown), we studied reciprocal
(C57BL/6 × M. spretus) × C57BL/6) F2 hybrid nuclei as
well. Again, it was the paternal chromosome that displayed preferential
DNase-I sensitivity in these F2 hybrids (Fig. 2A), with the
M. m. domesticus chromosome now being the more readily
digested one. This indicates that the observed preferential paternal
DNase-I sensitivity in the interspecific hybrids did not result from
DNA sequence polymorphisms between M. m. domesticus and
M. spretus.
Parental chromosome-specific nuclease
sensitivity in the U2af1-rs1 gene. A, paternal
DNase-I sensitivity and hypersensitive sites in the 5-UTR. A
BglII RFLP was used to analyze adult liver nuclei, isolated
from (C57BL/6 × M. spretus) F1 and ((C57BL/6 × M. spretus) × C57BL/6) F2 mice. After incubation at
increasing concentrations of DNase-I (lanes 1-7 were at 0, 20, 50, 100, 150, 200, and 300 units/ml, respectively), DNA was
extracted from the nuclei, digested with BglII,
electrophoresed, and probed with fragment 1. To the left,
the BglII fragments in C57BL/6 (M) and M. spretus (S) adult livers, and the 1.8-kb
BglII-NotI digestion product that derives from
the unmethylated paternal chromosome in the (M × S) F1
adult liver. For the (M × S) F1 DNase-I series, the
ratios of the intensities of the maternal (5.6 kb) and the paternal
(4.3 kb) bands were 1.1, 1.5, 3.2, and 3.7 for lanes 1-4,
respectively. Arrows indicate DNase-I digestion products corresponding to HSS. Fragment sizes are in kb. B, a
promoter-specific paternal DNase-I HSS in adult brain. In the
left panel, BglII-digested (M × S) F1 nuclei DNAs, probed with fragment 1, showing the presence of
the two HSS in the 5
-UTR, and a prominent HSS in the promoter. DNase-I
concentrations (lanes 1-7) in this analysis were as in A. The ratios of the intensities of the maternal (5.6 kb)
and the paternal (4.3 kb) bands are 0.9, 1.0, 1.5, 3.4, and 4.9 for lanes 1-5, respectively. In the right panel, the
same DNase-I-digested nuclei DNAs were digested with BglII
and HpaII. The methylation-sensitive restriction enzyme
HpaII digested sites on the unmethylated paternal allele
(4.3-kb fragment) exclusively and thereby allowed analysis of DNase-I
sensitivity on the maternal chromosome. The weak band of 5.3 kb
corresponds to a single, partially demethylated HpaII site
on the maternal chomosome 1 kb upstream of U2af1-rs1 (see also Fig. 3). Fragments corresponding to DNase-I HSS are indicated with
arrows. C, paternal chromosome-specific nuclease sensitivity in 3
part of the U2af1-rs1 gene. In the left
panel, DNase-I digested (M × S) F1 liver nuclei
DNAs (the DNase-I concentrations in 1-8 were 0, 20, 50, 100, 200, 300, 500, and 800 units/ml, respectively) were digested with
BglII and SacI, electrophoresed, and probed with fragment 1. The paternal 1.3-kb fragment is more sensitive to
DNase-I than the maternal 2.6-kb fragment. The ratios of the 2.6- and
1.3-kb bands are 1.4, 1.6, 4.0, and 4.4 for lanes 4-7, respectively. In the middle panel, the hybrid liver nuclei
were incubated for increasing periods of time (0, 1, 2, 5, 7.5, 10, 15, and 30 min, in lanes 1-8, respectively) with
MspI (at 10,000 units/ml). DNA was extracted and digested
with BglII and SacI, electrophoresed, and probed
with fragment 1. The ratios of the 2.6- and 1.3-kb bands are 1.6, 3.5, and 6.8 for lanes 3-5, respectively. In the right
panel, analysis of MNase sensitivity. (M × S) F1 hybrid liver nuclei were incubated with increasing concentrations of
MNase (0, 0.15, 0.3, and 0.8 units/ml, in lanes 1-4,
respectively), DNAs were extracted, digested with
BglII+SacI, electrophoresed, and probed with
fragment 1. The ratios of maternal (2.6 kb) and the paternal (1.3 kb)
bands are 0.7, 0.5, and 0.35 in lanes 1-3, respectively.
In brain, where in contrast to other tissues U2af1-rs1
expression is very high (6), we detected an additional strong HSS in
the promoter region (Figs. 1A and 2B). In a
maternal chromosome-specific DNase-I assay we demonstrated that this
promoter HSS was also present only on the paternal chromosomes. Hence,
F1 hybrid brain nuclei were incubated with increasing concentrations of
DNase-I, and genomic DNA was extracted and then digested with both
BglII and with the methylation-sensitive restriction
endonuclease HpaII. Because HpaII leaves intact
the maternal allele, which is methylated in this domain (Fig.
3), and completely digests the
unmethylated paternal allele, DNase-I sensitivity was thus assayed
specifically on the maternal chromosomes, which did not show any HSS
sites in the U2af1-rs1 domain (Fig. 2B). The
paternal chromosome-specific promoter HSS was not as pronounced in
liver (Fig. 2A) or embryonic stem cells (see Fig.
5A), where U2af1-rs1 expression levels are lower
than in brain (6). However, in (C57BL/6 × M. spretus) F1 day 15 fetuses we detected paternal hypersensitivity in the promoter
region, albeit not as strong as in adult brain, possibly due to the
proportional contribution of brain (or other high expressing tissues)
in these fetuses (not shown).
To establish whether the two HSS in the 5-UTR were solely responsible
for the preferential paternal DNase-I sensitivity or whether a
generalized sensitivity difference is established over a larger domain,
we analyzed DNase-I sensitivity in the 3
part of the gene (in
SacI+BglII digests). No HSS were detected in this part of the gene in brain and liver, but in both tissues, the paternal
chromosome was again more sensitive to DNase-I than the maternal
chromosome (Fig. 2C). Hence, preferential paternal
sensitivity appears to be established in the entire
U2af1-rs1 gene. In both liver and brain, we also analyzed
the parental chromosomes for their accessibility to the
methylation-insensitive restriction endonuclease MspI, which
has multiple recognition sites throughout the gene and its promoter
(Fig. 1B). Like in the DNase-I assays, a pronounced
difference in sensitivity between the parental chromosomes was
detected, with paternal chromosomes displaying much higher sensitivity
to MspI than maternal chromosomes, both in the polymorphic BglII fragment covering the entire gene (not shown) and in
the SacI-BglII fragment covering the 3
part of
the gene (Fig. 2C).
To investigate further the nature of the differential chromatin
conformation, we analyzed the U2af1-rs1 domain for its
sensitivity to MNase, an enzyme that digests preferentially the linker
DNA between nucleosomes. Hence, nuclei from (C57BL/6 × M. spretus) F1 livers were incubated with increasing concentrations
of MNase, and the BglII RFLP polymorphism was used to
differentiate between the parental chromosomes. We found that both in
the BglII fragment covering the entire gene (not shown) and
in the SacI-BglII fragment covering the 3 part
of the gene, maternal and paternal chromosomes were equally sensitive
to MNase. In particular, the degree of MNase digestion of the maternal
and the paternal SacI-BglII fragments related to
their respective lengths, with the 2.6-kb maternal fragment being about
twice as sensitive as the 1.3-kb paternal fragment (Fig.
2C).
Because
preferential paternal DNase-I sensitivity was detected in all the
tissues analyzed (liver, brain, fetus, and stem cells), it was of
interest to determine whether maternal chromosome-specific methylation
was equally widespread. Indeed, the NotI restriction site in
the 5-UTR was maternally methylated and paternally unmethylated in all
embryonic and extraembryonic tissues analyzed, including brain, choroid
plexus, liver, spleen, kidney, heart, skeletal muscle, and placenta
(not shown). The paternal chromosome is not required for the
establishment and maintenance of maternal methylation in
U2af1-rs1, because the NotI restriction site was
fully methylated in fetuses that were Matdi-11. Conversely, the
paternal chromosome is maintained unmethylated during development, even
in the absence of the maternal chromosome, because in Patdi-11 fetuses,
the NotI restriction site was completely unmethylated (data
not shown, but see Fig. 3). To determine the extent of maternal
methylation in more detail, we analyzed the allelic methylation status
of all the HpaII restriction sites in three adjacent
HindIII fragments (together spanning 10.8 kb of DNA; see
Fig. 1) by comparing the MatDi-11 and Patdi-11 fetuses and tissues
(Fig. 3). All HpaII restriction sites in the gene and in the
promoter were methylated on the maternal allele and appeared fully
digested by HpaII on the paternal allele (probes 1 and 13).
However, a HpaII restriction site at 1 kb upstream of the
gene was partially demethylated on the maternal allele in liver and
brain (probe 13), and two HpaII sites at ~4 kb downstream
of the gene were methylated on both parental chromosomes in the fetus
and in liver (probe 4). Also in brain the latter two HpaII
sites were fully methylated on the paternal allele, but one of these
two sites was partially demethylated on the maternal chromosome. It
follows that the domain that is methylated on the maternal allele and
unmethylated on the paternal allele comprises at least the entire
U2af1-rs1 gene and its promoter.
A PstI polymorphism between C57BL/6 (5.5-kb fragment) and
M. spretus (7-kb fragment) was used to analyze DNase-I
sensitivity allele-specifically in the biparentally methylated region
downstream of U2af1-rs1. For the chromatin analysis of this
region we used fragment 4, which is 4 kb downstream of the gene, to
probe Southern blots. The maternal and paternal chromosomes appeared
equally accessible to DNase-I in this region, both in liver (Fig.
4A) and in brain (not
shown).
In addition, two closely linked, strong HSS were detected in liver (Fig. 4A) but not in brain (not shown), and these two sites are likely to be on both parental chromosomes (Fig. 4A). To map the two HSS more precisely, we digested the DNase-I treated liver nuclei DNAs with the enzyme EcoRV and hybridized the electrophoresed DNA with probe 4 (not shown). This indicated that the two HSS are 5.5 kb downstream of the gene (Fig. 1). This location was verified because no strong HSS were detected in the 2.8-kb HindIII fragment downstream of U2af1-rs1 (Fig. 4B). However, a less prominent HSS was present in liver and brain in this HindIII fragment (Fig. 4B). The relative weakness of this HSS, however, did not allow us to determine (using the PstI polymorphism) whether it was also present on both parental chromosomes. Finally, with probe 6 we analyzed DNase-I sensitivity in a 4.5-kb BamHI fragment located upstream of the U2af1-rs1 gene (Fig. 1A), but no strong HSS were apparent in this upstream region (not shown).
Developmental Regulation of Parental Chromosome-specific Chromatin Conformation and DNA MethylationTo determine whether the differential chromatin structure and the maternal chromosome-specific DNA methylation in the U2af1-rs1 domain are present before implantation and whether both parental genomes are required for the establishment and maintenance of these imprints, we performed DNase-I and methylation studies on monoparental and biparental ES cells, which represent the blastocyst stage of development, and derive from inner cell mass cells. New Ag, Pg, and normal (M. m. domesticus × M. spretus) F1 ES cell lines were derived for these assays, which allowed analysis of early passage (<passage 6) cells.
Three early passage Ag ES cell lines were analyzed, all of which showed
DNase-I hypersensitivity and complete absence of methylation in the
U2af1-rs1 domain (Fig.
5A). Hence, only the genome of
paternal origin appears to be required for the establishment and
maintenance of the paternal chromatin structure without DNA
methylation. Conversely, for the establishment of the "closed"
maternal chromatin conformation with full DNA methylation, it is only
the maternal genome that is required. In the five early passage Pg cell
lines we analyzed, the NotI restriction site in the
U2af1-rs1 gene was fully methylated, and no DNase-I HSS were
detected in the 5-UTR (Fig. 5A). We obtained the same
result by analysis of DNA methylation in Pg (day 9.5) embryos, in which
the U2af1-rs1 gene was also methylated (not shown). The
U2af1-rs1 methylation in the Pg ES cell lines, however, was
found not to be stably maintained on prolonged culture, and in several
of the lines, loss of methylation was observed (not shown). Our
analysis of early passage monoparental ES cell lines demonstrates that
already at the blastocyst stage, at least in the inner cell mass, the
parental chromosome-specific chromatin organization and DNA methylation
are fully established in the U2af1-rs1 domain.
To investigate the situation in biparental ES cells, in a parental
chromosome-specific manner, we derived new (M. m.
domesticus × M. spretus) F1 stem cell lines and
analyzed them for allelic DNase-I sensitivity and DNA methylation using
the BglII polymorphism between the two mouse species (Fig.
1). The hybrid cell lines were obtained by in vitro
fertilization of M. m. domesticus eggs with M. spretus sperm, followed by in vitro culture of the
hybrid embryos to blastocysts, from which ES cells were then derived. In total, five early passage hybrid lines were analyzed.
U2af1-rs1 was found to be maternally methylated in two of
the hybrid lines (SF1-1, Fig. 5A; SF1-11), in which the
paternal chromosome was sensitive to DNase-I and had two DNase-I HSS in
the 5-UTR. In the three other hybrid lines (SF1-3, SF1-10, and
SF1-19), the U2af1-rs1 gene was mostly or completely
unmethylated on the maternal allele (and on the paternal allele), and
both alleles were similarly sensitive to DNase-I (not shown). Hence, in
all monoparental and biparental ES cell lines analyzed, as in the adult
tissues and fetuses, allelic methylation correlated with parental
chromosome-specific chromatin conformation. Parental chromosomes
sensitive to DNase-I in the U2af1-rs1 domain and with
hypersensitivity in the 5
-UTR always had the U2af1-rs1 gene
unmethylated.
To determine whether the absence of methylation on the maternal allele in some of the biparental hybrid lines was due to the genetic background of these ES cells, we have also analyzed U2af1-rs1 methylation levels in 17 homozygous ES cell lines of the 129/Sv and C57BL/6 genotypes, which were all of higher passage (>passage 10). Although nine of these lines displayed the expected methylation level of ~50% at the NotI restriction site, eight others were fully unmethylated at this site (data not shown).
The levels of U2af1-rs1 expression were relatively low in
the undifferentiated Ag and normal, hybrid, ES cell lines (Fig. 5C). They may therefore not be very significant relative to
the overall methylation and chromatin status of the parental
chromosomes in these lines. However, the allele-specificity of
expression correlated absolutely with parental chromosome-specific DNA
methylation and chromatin conformation. No expression was detected on
Northern blots in Pg ES cells, and in the hybrid lines with
differential chromatin structure and methylation (SF1-1 and SF1-11),
exclusive paternal expression was detected by allele-specific reverse
transcription-polymerase chain reaction analysis. In the hybrid
lines with a nuclease-sensitive chromatin conformation and no DNA
methylation on either parental chromosomes (SF1-3, SF1-10, and
SF1-19), we detected biallelic expression (data not shown). On
in vitro differentiation of the Ag and normal, hybrid, ES
cell lines, higher levels of U2af1-rs1 expression were
acquired (Fig. 5C). Given the significant increase (~8
times) in gene expression, we were interested in determining the
allelic chromatin conformation in the differentiated cells in
comparison to the undifferentiated cells. Like the undifferentiated ES
cells (and all other tissues analyzed) the differentiated cells displayed the two DNase-I HSS in the 5-UTR. However, on
differentiation they had acquired paternal DNase-I hypersensitivity in
the promoter region (Fig. 5B). This shows, together with our
comparison of tissues expressing very low (liver) or high (brain)
levels of U2af1-rs1 mRNA (Fig. 2, A and
B), that the paternal promoter HSS is likely to be directly
associated with U2af1-rs1 expression, whereas the two HSS in
the 5
-UTR may be regarded as permissive sites whose presence does not
reflect levels of expression.
In
the paternally expressed U2af1-rs1 gene, the parental
chromosomes acquire distinct chromatin conformations during early embryonic development. On the unmethylated paternal chromosome, an
"open" structure becomes established, characterized by generalized DNase-I and MspI sensitivity and by the presence of two
prominent DNase-I HSS in the 5-UTR. The maternal chromatin, in
contrast, acquires a conformation that is much less sensitive to these
nucleases and that does not display DNase-I hypersensitivity. In
addition, the maternal allele becomes methylated. These opposite
properties of the parental alleles appear to be constitutive, because
differential methylation was present in all embryonic, extraembryonic,
and adult tissues analyzed, and the chromatin structural difference was
detected in liver and brain, in whole fetuses, and in ES cells. Furthermore, because the paternal HSS in the 5
-UTR are present already
in cells from the blastocyst, these sites and/or the factors bound at
them could be crucial for the imprinting of the U2af1-rs1 gene.
The open paternal chromatin conformation was detected both in tissues with high U2af1-rs1 expression (brain, differentiated ES cells) and in tissues with low levels of expression (liver, ES cells). We propose that in this state, the gene is accessible to transcription factors and therefore permissive to expression. The levels of expression may depend on the tissue-specific availability of such trans-acting factors. In addition to this consistent property, the chromatin organization at the presumed regulatory sequences of the gene (24) varies according to the levels of U2af1-rs1 expression. Thus, an additional, paternal HSS was readily present in the promoter in brain and in differentiated ES cells but was not detected in liver and in undifferentiated ES cells and may therefore be directly associated with paternal gene expression.
We found the U2af1-rs1 gene to be maternally methylated and paternally unmethylated in all embryonic and extraembryonic tissues analyzed. These included adult kidney, heart, skeletal muscle, and liver, tissues that have either very low or nondetectable levels of U2af1-rs1 expression (6). This shows that the maternal methylation, like the parental chromosome-specific chromatin conformation, may be permissive for allelic expression of U2af1-rs1 and does not reflect levels of paternal expression.
Differences in nuclease sensitivity have been found previously at the promoter of the imprinted H19 gene (4). In addition, Shibata et al. (25) have independently identified the paternal chromosome-specific HSS in the U2af1-rs1 gene and examined allele-specific methylation but only in adult liver. Our more comprehensive studies examined a range of tissues and developmental stages, using monoparental in addition to biparental material and employing different nuclease probes. In particular, we document generalized paternal chromosome-specific DNase-I and MspI sensitivity over a larger region comprising the entire U2af1-rs1 gene.
By comparing HpaII digestion profiles in DNAs from Matdi-11 and Patdi-11 mice, we estimate the domain of allele-specific methylation at least to encompass the entire gene. This appears to coincide well with the region of generalized differential nuclease sensitivity. Outside this region, biallelic methylation was detected, and DNase-I HSS were present on both chromosomes ~4 kb downstream of the gene. It is likely that these downstream HSS are not associated with U2af1-rs1 expression. The U2af1-rs1 gene appears to be a recent retrotransposon, located within an intron of a larger gene that is not imprinted (Murr-1; Ref. 34), so it is possible that the downstream HSS are involved in the expression of this new gene.
The relative contributions made by methylation and chromatin structure to the maintenance of monoallelic expression of U2af1-rs1 are not easy to quantitate; the two were invariably linked in all the material we examined. Methylation can repress transcription directly by inhibiting transcription factor binding (35, 36), although some factors are indifferent to the methylation of CpGs in their recognition sites (37). Demethylation by 5-azacytidine is sufficient to induce transcription factor binding, HSS formation and derepression of silent genes (38, 39), but not invariably (40). There is also evidence for a less direct mechanism in transcriptional repression. Methylated transfection constructs appear to require organization into chromatin before expression becomes repressed (41, 42). Methyl-CpG-binding proteins, whose binding to DNA is determined by the density of methylation rather than sequence, are thought to be at least partially involved in this indirect repression of transcription (37, 43-45). It may be significant that we found the methylated maternal U2af1-rs1 domain to be highly resistant to MspI in nuclei, but to which extent this can be accounted for by methyl-CpG-binding proteins bound to these CpG-containing restriction sites remains to be determined.
At first glance, it may seem surprising that we detected no difference in the rate of digestion by MNase of the parental alleles, despite marked differences in sensitivity to DNase-I and MspI in the same nuclei. This would appear to indicate that both alleles are similarly packaged into nucleosomes and that if the closed chromatin conformation of the maternal allele represents a more compact or higher ordered structure, this has not altered accessibility of linker DNA to MNase. We cannot, however, rule out the possibility of more subtle differences in nucleosomal organization. Several studies suggest that the composition of nucleosomes, including the distribution of linker histone H1 (46-48) and acetylation of core histones (49-51), may differ on active and inactive genes, and similar differences may exist between the active and repressed alleles of imprinted genes.
Developmental Control of Chromatin Conformation, DNA Methylation, and Allelic ExpressionWhether methylation and/or chromatin
organization constitute the primary imprinting signals of the
U2af1-rs1 gene and initially determine monoallelic
expression remains to be determined. The absence of methylation and the
hypersensitivity in the 5-UTR in early passage Ag stem cells (derived
by pronuclear transfer) and full methylation and a highly
DNase-I-resistant chromatin conformation in early passage Pg ES cells
(derived by activation of eggs), however, indicate that germline
imprints must exist on both paternal and maternal alleles. Recently,
using a polymerase chain reaction assay to detect methylation of
HhaI sites (up to four) at the U2af1-rs1
promoter, Hatada et al. (24) reported that these sites were
unmethylated in oocytes and two-cell embryos. This region is also
unmethylated in sperm DNA in which, in contrast, we found the
NotI restriction site in the 5
-UTR to be fully
methylated.2 The maternal
allele has previously been found to become methylated by embryonic day
11 (24), and our results from early passage ES cells indicate that
distinct methylation and chromatin states exist already at the
blastocyst stage. Expression of U2af1-rs1 RNA is detected at
the two-cell stage, preferentially or exclusively from the paternal
chromosome (24, 31), and therefore in the apparent absence of
allele-specific methylation. It is possible that a germ-line
methylation imprint does indeed exist but was not included in the
regions examined so far. For example, at the imprinted H19
locus, HpaII and HhaI sites close to the promoter are methylated both in sperm and oocyte DNA, whereas sites further upstream are differentially methylated in the gametes, remain so in
preimplantation embryos, and could constitute an imprinting signal
(13).
What could give rise to monoallelic expression, however, if there was
indeed no differential methylation in the zygote? Although it is not
technically feasible to assay chromatin organization in preimplantation
embryos, there are grounds for believing that distinct chromatin
states, sufficient to determine monoallelic expression, could become
established on the parental chromosomes at such early stages. The
oocyte and sperm derived chromosomes both undergo remodeling in the
fertilized oocyte (52), in particular, histones must replace protamines
on the sperm chromosomes. It is therefore possible that the
U2af1-rs1 gene could assume a chromatin organization
permissive to expression preferentially in the paternal pronucleus. In
this context, it is interesting to note that U2af1-rs1 has
been reported to be among the earliest known genes to be activated from
the embryonic genome (24, 31). In contrast, in the absence of
transcriptional activation, the maternal allele may adopt a closed
conformation that is subsequently "fixed" by methylation. The
direct repeats in the 5-UTR (6, 7), a possible characteristic of
imprinted genes (53), could influence local DNA structure (54) and be
involved in this early regulatory decision.
In three of the newly derived hybrid ES cell lines and in about half of the higher passage homozygous lines we analyzed, the U2af1-rs1 gene was biallelically unmethylated. This may indicate that on derivation and subsequent culture of stem cells, the allelic methylation and chromatin conformation (hybrid ES cells) are not faithfully maintained. Indeed, we observed loss of U2af1-rs1 methylation on prolonged culture of the Pg ES cell lines, and in other imprinted genes changes in methylation levels have also been observed on culture of stem cells (55). The consequences for gene expression and development of epigenetic changes that result from in vitro manipulation during early development are being investigated in our laboratory.
Finally, our analysis of monoparental material allows us to
conclude that the distinct methylation and chromatin states of the
parental chromosomes are established and maintained independently. The
methylation state of U2af1-rs1 in Patdi-11 DNA appeared like two copies of the paternal allele and like two maternal alleles in
Matdi-11 DNA. Therefore, we do not envisage the necessity of trans-sensing between alleles (26-29) or the operation of a
"counting mechanism" (16, 26). Furthermore, the fact that we
detected a maternal chromatin and methylation epigenotype in the early passage Pg ES cell lines and in Pg embryos indicates that the maternal
imprint is correctly established without the input of the paternal
genome. The same applies to the paternal imprint because Ag ES cell
lines had the correct paternal epigenotype, characterized by the
DNase-I HSS in the 5-UTR and unmethylated DNA. This could therefore be
in contrast to the situation for clusters of imprinted genes, where
normal biallelic inheritance appears to be necessary for some aspects
of imprinting (16, 29).
We are grateful to W. Dean for assistance with mouse embryology, to I. Hatada and A. Nabetani for plasmid pSP2, to B. Cattanach for kindly providing disomy-11 mice, to N. Nakatsuji for ES cell DNAs, to K. Kaestner for the genomic mouse library, and to T. Forné and W. Reik for careful reading of the manuscript.