transcripts of a A globin gene in proliferating and differentiated AEV cells. To
induce differentiation, the proliferating HD3 cells were incubated with the IMD
inducer at 42°C (see Methods section for details).
Aliquots were taken from the cell suspension at different time intervals after
the beginning of induction and the percentage of cells producing haemoglobins
was calculated using benzidine staining. It was found to be correspondingly
≤1%, 18%, 30% and 42% in the samples taken 24, 48, 52 and 76 h after the beginning of induction. The percentage of
the dead cells present at the same samples was calculated using trypan blue
staining and was found to be correspondingly 9%, 11%, 18% and 40%. Hence, four
days after the start of induction, about 70% of cells still alive produced
haemoglobins. The morphology of these cells was checked by light microscopy
after staining with Giemsa. Proliferating cells are big, with huge nuclei, and
more or less oval in shape. After incubation for 4 days under conditions
favouring differentiation, one could observe a number of differentiated (small
almost square) cells with picnotic nuclei originating, apparently, from large
(precursor ?) cells and from cell clusters (not shown).
The RNA probe recognising the transcripts of the
a A globin gene was prepared as described in "Methods"
and used for hybridisation in situ on
the non-induced cultured chicken erythroblasts (line HD3). The results of our
experiments show that the a A gene is indeed transcribed in proliferating HD3 cells (Figure 5 A, B). This globin RNA is not
randomly distributed within the nuclear volume. There is a clear concentration
of the hybridisation signal around nucleoli clearly visible in phase contrast (Figure 5 A', B') and also, in some
instances, at the nuclear periphery, in addition to faint tracks in the
nucleoplasm.
When HD3 cells were induced to differentiate the
situation changed drastically. The strongest signal was then present in the
cytoplasm (Figure 5 C-C'', D) in an
apparently homogeneous manner. The pattern of nuclear transcripts had also
changed: their distribution differed extensively from that observed in
non-differentiated cells. Most of the RNA identified by the a A globin probe could be observed within one or two intensively
stained spots (Figure 5 C-C'', D).
These might represent the processing centres of pre-mRNA. The confocal series (Figure 5 C-C'') and DAPI staining (not
shown) indicate that these, apparently spherical bodies are distinct from the
nucleoli, outlined by globin RNA in the uninduced cells (Figure 5 A,A', B,B').
It seems evident that the amount of nuclear staining in proliferating and differentiated HD3
cells is almost the same, whereas the pattern
of distribution changes drastically. It is hence likely that after
induction, the expression of globin proteins commences in AEV cells, because
the pre-mRNA is released from the nuclei.
III. Discussion
Although the domains of b-globin genes in human and
chicken have been extensively studied over past 25 years, many questions
concerning the regulation of b-globin gene expression (including switching from the embryonic to
the adult expression pattern) remain unsolved. Here we have demonstrated that
in AEV-transformed erythroid cells expression of globins is regulated in both
transcriptional and post-transcriptional levels. Although it was shown
previously, that an LCR-like positive regulatory element (in human cells known
as HS -40 (Higgs et al, 1990)) is essential for expression of b-globin genes, the correct expression in erythroid cells may
depend on a negative regulatory element described here. We have demonstrated
that, being methylated, this regulatory element ensure 5X suppression of the
activity of a D gene promoter in a model experiment with aDpromoter-CAT gene cassette transfected to
cultured chicken erythroid cells. In a normal chromatin context this effect is
likely to be even more profound. Indeed, the gene silencing by CpG methylation
may depend on a certain reorganization of the chromatin structure (Razin, 1998)
and it is known that transfected plasmids do not fully acquire the normal
chromatin organization.
An interesting observation made in the present
study is that a
A gene-specific transcripts are virtually absent from cytoplasm of immature
erythroid cells although they can be easily detected in the nuclei. Hence it is
likely that beginning of expression of globin proteins upon differentiation of
erythroid cells becomes possible because pre-m-RNA is released to undergo
processing and to leave nuclei. This suggests that there is a special control
mechanism that regulates the destination of the primary transcripts, by
targeting them to special nuclear compartments placed, possibly, on the
processing and transport pathways. Looking at the distribution of globin RNA in
non-differentiated cells, one can propose that the peri-nucleolar area serves
for the temporary storage (and possibly for subsequent destruction) of transcripts
that were unable to pass to the processing centres. Conversely one may simply
observe a compartment on the normal processing pathway, which is blown-up due
to a block in the transport system downstream. Indeed, Chan and Ingram [Chan,
1973 #509] showed many years back that nuclei of in vitro cultivated chicken blood islands contain globin mRNA many
hours before the latter starts to show up in the cytoplasm. Furthermore, there
was always a suspicion that the nucleoli might be involved somehow in gene expression,
beyond the mere contribution of ribosomes to the protein biosynthesis machinery
(e.g.: cf. [Deak, 1972 #511; Pederson, 1999 #527])
IV. Materials and Methods
A. Cell culture and DNA transfection
Avian erythroblastosis
virus (AEV)-transformed chicken erythroblasts of the line HD3 (clone A6 of line
LSCC (Beug et al, 1979)) and chicken lymphoid cells (line Hp50) were grown in
suspension in Dulbecco modified Eagle's medium supplemented with 8% fetal
bovine serum and 2% chicken serum. Transfection of DNA into these cells was
performed with the "lypofectin" transfection reagent (Gibco-BRL), as
described in the manufacturer's manual. In standard experiments, 106
cells were transfected with either 1 mg of methylated or
non-methylated constructs or with equimolar amount of vector DNA. To monitor
the efficiency of transfection, the cells were cotransfected with pSV-b-Galactosidase Control
Vector (Promega). The activity of the CAT (chloramphenicol-acetyl-transferase)
and b-gal
genes was assayed in cellular extracts 60 h after transfection. To induce
erythroid differentiation of growing HD3 cells, the inducer (IMD,
isoquinolinylsulphonil-2-methylpiperasine-dichloride) was added to the cell
suspension up to a final concentration of 20 mM and, thereafter, the cells were
cultivated at elevated temperature (42°C instead of 37°C). At the beginning of
differentiation the concentration of cells in suspension was adjusted to 5x105 per ml.
B. Preparation of DNA constructs
All manipulations with
recombinant DNA were carried out as described (Maniatis, 1982). The initial
vector containing the CAT gene expressed under the control of aD globin gene promoter aDpCAT3) has been described
previously (Razin et al, 1999). The DNA fragment showing different methylation
pattern in erythroid and non-erythroid cells (0.65 kb fragment of the upstream
area of chicken a-globin gene domain) was
excised from the insertion of the previously described recombinant clone a5HR ((Razin et al, 1991),
Gene Bank accession number: X54965) by double digestion with Fak I and Hae II
restriction endonucleases. This fragment was inserted into Mlu I site of aDpCAT3 vector after the ends
of both the vector and the insertion were made blunt. The clone bearing the
recombinant plasmid with the CpG-rich DNA fragment inserted in the same
orientation (versus promoter) as in the genomic chicken DNA was selected and
used in further experiments. From this recombinant construct the CpG-rich DNA
fragment was excised by cleavage with Sac I and Nhe I restriction endonucleases.
The excised fragment was methylated in
vitro using SssI methylase (Biolabs). The degree of methylation was
monitored by digestion of aliquots of reaction mixture with Hpa II restriction
enzyme. Methylated DNA fragment was reinserted into dephosphorylated vector DNA
and circular DNA was purified by preparative agarose gel electrophoresis.
C. Analysis of chloramphenicol-acetyl-trancferase and b-glactosidase activities in cell extracts
Promega assay systems were
used in both cases, and enzyme activity was determined exactly as described in
the manufacturer's manuals. To determine the activity of
chloramphenicol-acetyl-transferase, thin layer chromatography was used. After
chromatographic separation, the spots containing non-modified chloramphenicol
and butyrylated forms were scraped from the chromatographic plate and the
radioactive signal was quantified in a liquid scintillation counter.
D. DNA hybridization (Southern analysis)
Chicken genomic DNA from
HP50 or HD3 cells was digested with either Msp I or Hpa II or Sma I restriction
enzymes, and additionally with Pst I. The digestion products were separated in
1.5% agarose gels and transferred on nylon filters "NYTRAN-PLUS"
(Schleicher&Schuel). Hybridization was carried out in "Rapid-hyb"
buffer (Amersham), as described in manufacturer's manual. The probes were
labelled with a32P dCTP using Megaprime DNA
labelling system (Amersham).
E. In situ
hybridization
To prepare a
strand-specific probe, the 1.8 kb chicken genomic DNA fragment containing the aA gene (for a genomic map
see [Recillas Targa, 1994 #459]), was cloned into the pSP73 Vector (Promega).
The fragment was then transcribed in the direction opposite to that of globin
gene transcription with the T7 RNA polymerase, using the Boehringer (Mannheim) kit
for preparation of digoxigenin-labelled RNA. Hybridization in situ was carried out according to the Boehringer (Mannheim)
manual as described before [De Conto, 1999 #502]. Briefly, HD3 cells were fixed
in 1% paraformaldehyde in PBS for 20 min at r.t. before treatment with a
solution of 70% ethanol and 3% H2O2, to suppress endogenous peroxidases. Cells were
then permeabilized with 0,2% Triton X-100 in PBS for 10 min, washed carefully
in PBS and immersed in 0,1 M glycine in PBS for 5 min. After rincing in PBS,
cells were treated with 0,25% acetic anhydride in 0.1M triethanolamine buffer
for 10 min, prior to incubation at 42°C for 16 hours with the
ribo-probe (0.5 ng/ml) in hybridization buffer (50% de-ionized formamide, 5x
SSC, 10% dextran sulphate, 2.5x Denhardt's solution, 10 mM dithiothreitol, 20
mM vanadyl ribonucleotide complex). After hybridization, the
digoxigenin-labelled probe was detected by incubation with anti-digoxigenin-AP,
FAB fragments (Boehringer (Mannheim)), followed by incubation with tyramide, as
described in the manual for the TSA-DIRECT (tyramide signal amplification) kit
(DuPont, NEN).
F. Confocal Laser Scanning Microscopy and image
analysis
Analysis of patterns of
globin RNA localization in HD3 cells was performed using the TCS (Leica
Germany) confocal imaging system, equipped with a 63X objective (plan apo; NA
1.4). For Cy3 excitation, an Argon-Kripton ion laser adjusted at 488 nm was
used. The signal was treated using line averaging, to integrate the signal
collected over 8 lines in order to reduce noise. For high resolution, we
defined a set of acquisition parameters, which took into account Nyquist's
principle. The confocal pinhole was closed to yield a minimum field depth
(about 0.6 mm), and focal series were
collected for each specimen. The focus step between these sections was
generally 0.3 mm and the XY pixelization
was set to 100 nm.
Acknowledgements
This work was supported by grant N 097 from the Russian State
Program "Frontiers in Genetics", by RFFI grants 99-04-49204 and 00-15-97772
(Scientific Schools) by EMBO fellowship given to Olga Iarovaia and by
"Chaire Internationale de Recherche Blaise Pascal de l'Etat et de la
Région d'Ile-de-France, gérée par la Fondation de l'Ecole Normale
Supérieure", given to Sergey Razin.
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