* Department of Molecular Biology, Max Planck Institute for Biophysical Chemistry, 370170 Göttingen, Germany; and Institute
of Biology, Department of Cytogenetics, Humboldt University of Berlin, 10115 Berlin, Germany
The Drosophila protein Hrb57A has sequence homology to mammalian heterogenous nuclear ribonucleoprotein (hnRNP) K proteins. Its in vivo distribution has been studied at high resolution by confocal laser scanning microscopy (CLSM) in embryos injected with fluorescently labeled monoclonal antibody. Injection of antibody into living embryos had no apparent deleterious effects on further development. Furthermore, the antibody-protein complex could be observed for more than 7 cell cycles in vivo, revealing a dynamic redistribution from the nucleus to cytoplasm at each mitosis from blastoderm until hatching. The evaluation of two- and three-dimensional CLSM data sets demonstrated important differences in the localization of the protein in the nuclei of living compared to fixed embryos. The Hrb57A protein was recruited to the 93D locus upon heat shock and thus serves as an in vivo probe for the activity of the gene in diploid cells of the embryo. Observations during heat shock revealed considerable mobility within interphase nuclei of this transcription site. Furthermore, the reinitiation as well as the down regulation of transcriptional loci in vivo during the recovery from heat shock could be followed by the rapid redistribution of the hnRNP K during stress recovery. These data are incompatible with a model of the interphase nucleus in which transcription complexes are associated with a rigid nuclear matrix.
Chromatin structure has been resolved at the nucleosomal level, yet the structural and compositional features defining the higher levels of organization of the interphase chromosome are hotly debated
issues. The chromosome constitutes the structural basis for
transcription and replication and may play a critical role in
the organization of pre-mRNA processing as well. These processes have to be regulated and coordinated in an efficient way according to the specific requirements of the
cell. The efficiency of in vitro transcription and processing
systems is significantly lower than those in vivo. This difference may be explained by the reduced local concentrations of these factors as well as a lack of long range chromosomal order in these soluble systems. According to
present knowledge, we assume that some ordered structure exists at the chromosomal level within the interphase
nucleus. In early developing Drosophila embryos the chromosomes are positioned inside the nucleus with a defined
centromere-telomere polarity following a rule first described by Rabl (1885; Swedlow et al., 1993 The functional organization of the nucleus is under investigation in a number of laboratories (for review see van
Driel et al., 1995; Strouboulis and Wolffe, 1996 Nascent transcripts within the nucleus are complexed
with proteins as heterogeneous nuclear (hn)1 RNP particles. It has been proposed that these particles are the true
substrates for the assembly of splicing complexes by the
addition of small nuclear (sn)RNP particles and non-snRNP splicing factors. The hnRNP particles presumably constitute
the vehicle for mRNA transport to the cytoplasm as well
(Mayeda and Krainer, 1992 Hrb57A is seen to be almost completely restricted to
puff 93D on salivary gland polytene chromosomes following heat shock treatment (Dangli and Bautz, 1983 Drosophila Strain
Drosophila melanogaster wild-type strain Oregon R-P2 (Allis et al., 1977 Antibodies
The generation and maintenance of the hybridoma cell line, Q18, secreting antibodies, mAb Q18, against the Hrb57A protein have been described (Saumweber et al., 1980 Fluorescent Deoxyribonucleotide Probe to the
The NH2-linked antisense 29-mer, 5 Squashed Polytene Chromosomes and Hybridization
The preparation and fixation of polytene chromosomes from larval salivary glands was described previously (Saumweber et al., 1980 DNA-RNA hybridization.
Chromosomes were washed in 2× SSC and
stabilized for 30 min at 80°C. Hybridization of the oligonucleotide to chromosomal RNA was carried out for 2 h without prior denaturation and using
a probe concentration of 7 ng/µl in 2× SSC containing 0.1% Tween 20. The
chromosomes were washed in 2× SSC/Tween, stained with 5 µM DAPI
(diamidino-phenylindol) or 3 µM Hoechst 33342, and mounted in glycerol-Mowiol 4-88 (Osborn and Weber, 1982 DNA-DNA hybridization.
Denaturation of the DNA as well as the hybridization of the labeled oligonucleotides to DNA was performed as described by Schmidt (1992) Whole Mount In Situ Fixation
Fixation of Drosophila embryos was carried out with slight modifications
of the method described by Mitchison and Sedat (1983) Heat Shock of Embryos
Flies in population cages were induced to lay eggs onto an agar plate covered with a gauze net. After appropriate staging of the embryos at room
temperature the gauze net was transferred to a plate in an oven at 37°C for
20-60 min. The embryos were then fixed as described above with all solutions warmed to 37°C.
A thermal microscope stage (Sensortek, Clifton, NJ) was used to heat
shock embryos during in vivo observations.
Immuno and DNA Staining of Fixed Embryos
All incubations and washing steps were done in conical tubes on a rotating
wheel. Antibodies were diluted in PBS containing 0.05% Tween 20 or, after
the RNA hybridization (see below), in 2× SSC containing 0.1% Tween 20. Fixed in situ embryos were incubated with the Q18 antibody using a concentration of 1-4 µg/ml and with the Cy3-coupled secondary antibody at 5 µg/ml, either at room temperature for 3-4 h or at 4°C overnight. Embryos
were washed at least three times for 15 min between each antibody in a
buffer vol of 1 ml.
DNA was stained for 15-30 min with 5 µm DAPI or 3 µm Hoechst
33342 without prior RNA digestion. Embryos were mounted in glycerol Mowiol 4-88.
RNA Hybridization in Fixed Embryos
Fixed embryos were first exchanged into 2× SSC buffer containing 0.1%
Tween 20. Hybridization was performed for 3 h at room temperature in
500 µl using the fluorescently labeled oligonucleotides at a concentration
of 500 ng/ml. Embryos were freed from unhybridized oligonucleotide by
washing successively in 5× SSC/Tween and 2× SSC/Tween followed by
immunostaining in the same buffer. Identical hybridization signals to the
Microinjection, Microscopy, and Image Analysis
Microinjection of antibodies into living Drosophila embryos was performed as described previously (Buchenau et al., 1993 Dyes were excited using the following laser lines of the microscope system: fluorescein at 488 nm and tetramethylrhodamine and Cy3 at 514 nm.
Depending upon the combination of dyes within the preparation, the following emission filters were used: LP515 (Schott, Mainz, Germany) or BP530
DF30 (Omega Optical Inc., Brattleboro, VT) for fluorescein; LP550, LP575,
LP610 (Schott), or BP590 DF35 (Omega Optical Inc.) for tetramethylrhodamine and Cy3. For every preparation containing two dyes, the respective single-labeled controls were prepared under identical conditions
and used for selecting the appropriate excitation wavelength and emission
filter combinations.
Images (8 bit) were acquired with an appropriate scanning time and
frame averaging. For double staining, the images of the two fluorophore
distributions were recorded separately and saved to separate channels of an
RGB image. Reconstructions of stereo images were performed using the
projection functions of the LSM310 software or NIH-Image (National Institutes of Health, Bethesda, Maryland). Additional image processing was
performed on some images which included contrast stretching, uniform
filtering, bit plane masking, and intensity quantitation using Scil Image
(Technical University, Delft, The Netherlands), NIH-Image (National Institutes of Health), Photoshop 3.0 (Adobe Systems, Mountain View, CA), and
Imaris 2.2.6 (Bitplane AG, Zürich, Switzerland). Quantitative image processing was performed on confocal laser scanning microscopy (CLSM)
data on a Silicon Graphics (Mountain View, CA) workstation using Scil
Image or the depth analyzer module of Imaris 2.2.6. The latter program
permits the interactive definition of polygons in three dimensional (3-D)
stacks of sequential sections in up to three different fluorescence channels
and calculates volume, mean, and integrated greyvalues for each of the
channels in three dimensions. Nuclear/chromosomal and cellular volumes
were outlined by such polygons for the determination of the mean pixel
intensities as calculated in Fig. 2 B. Masks for the 93D subnuclear region were generated from the Fl-P2 oligonucleotide fluorescence image stacks
by intensity thresholds and used to calculate the distribution of the
Hrb57A protein coincident signal in comparison to the protein signal in
the total nucleus. Minimal translational distance measurements such as
those shown in Fig. 7, D and E were calculated from 2-D maximal intensity 3-D projection images using NIH-Image on a Macintosh Power PC.
Dynamics of the Hrb57A Distribution in Living
Embryos: Nuclear Import and Mitotic Distribution of
the Hrb57A Protein
Fixation may introduce artifacts through the aggregation of
structural components, the destruction of sensitive biological structures, or by selective extraction of components. In
addition, the temporal dimension in biological processes is
lost or often obscured by fixation. Therefore, we concentrated on in vivo observations of the RNA binding protein
Hrb57A to track the disposition of zygotic transcription
and RNA processing loci in early Drosophila embryos. The
monoclonal antibody Q18, specific for Hrb57A, was fluorescently labeled and microinjected into living embryos
several nuclear cycles before the formation of the cell
membranes (nuclear cycle 14; Foe and Alberts, 1983 Hrb57A showed a dynamic redistribution from the cytoplasm to the nuclei at the time of the initiation of massive zygotic transcription in early embryos. Fixed embryos of the
nuclear cycles 10-12 were characterized by strong cytoplasmic staining with very few accumulations of Hrb57A within
the interphase nuclei (Fig. 1 A). In contrast, embryos of
the cycle 14 showed an exclusively nuclear Hrb57A signal (Fig. 1 B) whereas cycle 13 embryos were clearly in transition, demonstrating examples of both patterns (data not
shown). From cycle 14 throughout the rest of embryogenesis, the protein was found in all interphase nuclei of fixed
embryos without any preferential tissue distribution (Fig.
1 C). In living embryos we observed similar cytoplasmic
antibody fluorescence in the early nuclear cycles and an almost exclusively nuclear staining at later stages. Fig. 1 D
shows an example of two optical sections through a living embryo during germ band retraction. By this time of development, about 12 h after microinjection, most of the
nuclei had divided two to three times after cellularization
and have gone through six to eight cell cycles since microinjection.
The labeling of Hrb57A in living embryos allowed us to
monitor continuously and directly cell cycle-dependent
changes in the distribution of the protein. Hrb57A was excluded from the nuclei until nuclear cycle 10 (data not
shown). Thereafter, following each mitosis we see a time-
dependent accumulation of the protein in every nucleus of
all of the many embryos injected. This observation is best
demonstrated by a montage of representative data shown in Fig. 2. Fig. 2 A is comprised of selected images from a
time series of 25 frames recorded from one such living embryo, demonstrating an increasingly nuclear localization of
the bulk of Hrb57A during the interphases of the nuclear
cycles 11-14. Already in the interphase of cycle 11 the nuclear area contains protein, the concentration of which increases dramatically in the next two cycles until by the end
of cycle 14 (Fig. 2 D) most of the protein resides in the nuclei. Computer animations of the recorded time series
show this dynamic transport and accumulation after each
mitosis. The kinetics of the Hrb57A nuclear import can be
represented semiquantitatively as shown in Fig. 2 B by
measuring the mean pixel intensities of the nuclear/chromosomal areas of a portion of a cycle 13 embryo, imaged
at 1 min intervals. In every nucleus of the living embryos at
cycle 13, the import of the protein was almost linear lasting through the entire interphase. In contrast, the dispersal of
the protein from the nucleus was achieved within 1-2 min,
presumably during the time between breakdown of the
nuclear envelope and formation of the metaphase plate.
This nuclear localization in vivo can be detected two cycles
earlier than that seen by the analysis of fixed preparations
(compare Fig. 2 to Fig. 1, A and B). There was complete
dissociation of Hrb57A from mitotic chromosomes in early
embryos (Fig. 2 C), whereas mitotic nuclei of gastrulating and older embryos continue to show small amounts of protein remaining in the volume defined by the metaphase
chromosomes (Fig. 2 D). This phenomenon in later embryos was best visualized by computer animation of time
lapse sequences of images. The protein may be associated
with the extrachromosomal protein layer surrounding metaphase chromosomes identified by electron microscopy (Hernandez-Verdun and Gautier, 1994 Comparison of the Distribution of Hrb57A in Fixed and
Living Interphase Nuclei of Embryos
Using the high spatial resolution of the fluorescence CLSM
we have analyzed the 3-D distribution of Hrb57A in the
nuclei of numerous fixed and living embryos. Fig. 3 A shows
a stereo image of the protein distribution in a nucleus from
the amnioserosa of a fixed embryo. Hrb57A was localized
in a number of optically resolvable spots throughout the
nuclear volume excluding the nucleoli, which can be identified as unstained domains. The number of discrete protein loci in such interphase nuclei was determined by intensity segmentation of the 3-D data sets and generation
of labeled binary objects. The representative nucleus of
Fig. 3 A contains about 200 Hrb57A spots. This number is
close to the number of Hrb57A-bound transcriptional loci
on polytene chromosomes and confirms our supposition
that the protein denotes gene loci sensitive to activation and binding of the hnRNP K in the embryonic nuclei.
A nucleus from the same tissue of a living embryo 5 h after the injection of rhodamine-labeled mAb Q18 is shown
in Fig. 3 B. In this case the unstained nucleoli were surrounded by a positively fluorescent nuclear volume punctated by discrete loci with higher concentrations of
Hrb57A. These loci are somewhat larger and fewer in
number than those resolved in the fixed embryos. Both
stereo images in Fig. 3 have been reconstructed from confocal sections acquired under optical conditions as nearly
identical as possible. Fig. 4 shows overviews of a field of
amnioserosa cells from another fixed (A) and another living (B) embryo which demonstrate that these differences
in the distribution of Hrb57A between fixed and living
embryos are highly reproducible and visible already in single confocal sections. We attribute the differences to a differential extraction of the protein as well as to changes in the chromatin structure introduced by the fixation procedure and/or to the dynamic movement of transcription sites
in living embryos (see Discussion).
Activation of a Transcriptional Locus
It has been observed previously that following heat shock,
the Hrb57A protein is concentrated exclusively on the
heat shock locus 93D of chromosome 3R in salivary gland
polytene chromosomes of third instar larvae (Dangli and
Bautz, 1983 A 29-base oligonucleotide with a sequence complementary to a repeated region in the 3
The distribution of Hrb57A in embryos fixed after a
heat shock of 20-60 min at 37°C showed dramatic changes.
Fewer nuclear loci were positive for Hrb57A and 93D always contained the highest concentration of the protein
(Fig. 6 C). Over 50% of the total nuclear Hrb57A protein
was coincident with 93D even after relatively short heatshock times. The extent of this heat shock response, i.e.,
the increased transcription of To follow the same process in vivo we injected embryos
of the blastoderm stage with rhodamine-coupled mAb
Q18. After an incubation time of 2-3 h at room temperature the embryos were heat shocked at 37°C either in an
incubator or by a thermo-controlled stage mounted directly onto the stage of the confocal microscope. The first
signs of a heat shock response were clearly visible 10-15 min after raising the temperature. At room temperature
the embryonic nuclei were characterized by a moderately
differential Hrb57A staining (Figs. 2 and 3), whereas after
heat shock they developed one, and in polyploid nuclei up
to a few, very intensely fluorescing spots (Fig. 7 A).
Dynamic Behavior of Transcriptional Loci in
Living Embryos
The redistribution of Hrb57A during heat shock to an almost exclusive localization at 93D (Figs. 6 C and 7 A) provided us with a system amenable for the study of the dynamic behavior of transcriptional loci in living embryos,
due to the reduced number of sites as compared with nonstressed embryos. We have observed literally thousands of
cells in many tens of living, heat shocked embryos. There
is constant movement of loci throughout the embryo, some of which may originate from rotation of whole nuclear contents whereas others are clearly local movements
of the transcription sites themselves. The exact nature of
the 3-D movement of the single 93D locus in 2N cells is often impossible to unambiguously determine. The types
and extents of movement can be more clearly examined
and documented in the polyploid cells with multiple 93D loci. Time series of 3-D data sets from heat shocked embryos are acquired at high spatial resolution. Computer
animated displays of the series show jitter, slow movements, rapid movements over both large and small distances, and apparently, both random walk and directed
movements. An example of one such nucleus in a series is
seen in Fig. 7, B-D. B is composed of 2-D image projections of a polyploid amnioserosa nucleus at successive
time points over a period of ~20 min. At the beginning of
the observation the nucleus exhibited 3 intensely fluorescing 93D loci (labeled a-c in the first schematic drawing in
C) lying adjacent to a nonfluorescent nucleolus. In computer animations of time series, such loci appeared to "jitter" around an average position, probably due to continuous small changes in the nuclear shape in vivo. This jitter
has been removed from the traces. With increasing time,
one of these loci, a, moved away from its original position,
exposing a fourth locus. Presumably, this "new" locus d
was not optically resolved from a at the beginning of the
recording. While the relative positions of the loci b-d and
the nucleolus remained almost constant during the observation period, a moved a distance of >3 µm in <10 min (relative distance trajectories are plotted in Fig. 7 D). Similar movements were observed in many of the polyploid
nuclei of all heat shock embryos. Fig. 7 E shows typical
traces of two body temporal distance measurements from
other nuclei in other embryos.
We were able to observe another type of dynamic behavior of Hrb57A in vivo after the transition from the high
(37°C) to normal temperature (25°C), i.e., during recovery
of the embryos from heat shock. Onset of recovery begins
immediately, as reflected by the change in the disposition
of Hrb57A at the 93D locus. The earliest recordings were
made at 1 min after the temperature drop and subsequent
images at 2 or 4 min intervals. The intensity of the Q18
staining of the 93D locus begins to decrease in almost all
loci immediately. Many new weaker loci appear throughout the nuclear volume. There is large variability in the
rate of appearance and number of resolvable new loci in
individual nuclei. The rate of recovery also is dependent
upon the extent and duration of the prior heat shock treatment. An example of recovery behavior is demonstrated
in Fig. 8. Two stereo image pairs of the amnioserosa of an
embryo are reconstructed from image stacks separated by 4 min in time after return to normal temperature. Local
accumulations of mAb Q18 in the two fully visible nuclei
in this field have been marked by numbers. The nucleus on
the left shows small reorganizations of the Hrb57A loci at
6 and 10 min into heat shock recovery, and the composite
loci are labeled 1 and 2 for simplicity. The nucleus on the
right displayed dramatic changes in the Hrb57A pattern at
these time points. One of the spots disappeared completely (3), another one became smaller (5), and two new
accumulations appeared (6 and 7). Computer animations
of the complete time series of this recovery show increasingly complex reorganization of the Hrb57A protein. These
dynamic changes cannot be attributed to a rotation of the
nucleus as a whole or to a simple translational mobility of
most of the loci as is documented in Fig. 7, B-D. We have
observed a large number of similar and more complicated dynamic redistributions of the Hrb57A protein during
heat shock recovery in many embryos. We conclude that
the redistribution of Hrb57A is causally related to the reactivation of gene expression that occurs in the cell nucleus during recovery from heat shock.
In this study we show the dynamic distribution of the
hnRNP K-homologous protein Hrb57A in the nuclei of
developing Drosophila embryos by in vivo immunostaining with the monoclonal antibody Q18. The protein was
originally isolated in hnRNP particles from Kc cells (Risau
et al., 1983 In fixed embryos we were able to distinguish ~200 discrete loci of the Hrb57A protein distributed throughout
the nuclear volume (Figs. 3 A and 4 A). This number of
loci closely approximates that which has been observed on
spread salivary glands where the protein is always associated with transcriptionally active sites on the chromosomes. The colocalization of the protein with transcription sites can be followed through other larval tissues with lower levels of polyteny like the Malpighian tubules (Saumweber, H., unpublished observations). By extrapolation we
presume that the protein accumulation denotes sites of
transcription activation of genes and hnRNP K binding in
the fixed embryonic nuclei.
There are striking differences in the distribution of the
protein in the nuclei of living embryos compared with fixed
preparations. We see the protein distributed throughout
the entire nucleus except for the nucleoli in vivo. The intensities within the nuclei are less differential than in the
fixed embryos, and individual loci are more difficult to resolve or appear to form larger aggregates, as can be seen in
the examples shown in Figs. 3 B and 4 B. We consider
three possible, not mutually exclusive explanations for the
difference between the appearance of fixed and live nuclei stained for Hrb57A. Extrapolating from studies on the distribution of fluorescently labeled histones in live and fixed
embryos, we suggest that some of these differences may be
attributable to changes in the chromatin structure introduced by the fixation procedure itself (Buchenau, 1996 As has been demonstrated for a number of other proteins involved in RNA metabolism in Drosophila (Dequin
et al., 1984 Dangli and Bautz (1983) One of the striking results of our experiments is the
demonstration that nuclear components, and transcriptional loci in particular, behave in a very dynamic manner
in the living embryo. The few in vivo studies of nuclei in
the literature corroborate this plasticity and movement in
the nucleus (Buchenau et al., 1993 We have taken advantage of the fact that the majority of
the Hrb57A protein is associated with the locus 93D after
heat shock to follow for the first time in vivo a specific
transcriptional locus, as well as the formation of new loci.
During heat shock, morphogenesis is slowed down, and
most metabolic reactions are greatly reduced. Despite this
reduction in metabolism, a large variety of movements of
the transcription loci can be observed throughout the embryo in all types of cells. We have described the types of
movements seen from computer animated displays of time
lapse sequences of 2- and 3-D data stacks. Examples of these movements of the 93D locus are documented in Fig. 7.
Changes in the distribution of chromosomal domains with
the differentiation state of a cell (Manuelidis and Borden,
1988 During recovery from heat shock the embryo can rapidly return to constitutive levels of transcription from the
93D locus with the concomitant reinitiation or activation
of other gene loci (Hogan et al., 1994 We emphasize that the phenomena described in this paper and documented in the figures have been observed in
diploid as well as polyploid nuclei of a large number of embryos, that the translocations of the 93D locus are sometimes even more rapid than shown here, and that the formation and dissolution of local concentrations of Hrb57A
occurs frequently in normal embryos as well as those recovering from heat shock. The distribution of Hrb57A
could not be as well resolved in living and as in fixed embryos, which suggests that many redistributions or local
movements of the transcription apparatus are occurring in
a time scale faster than our present technical imaging resolution. These in vivo results directly support the idea that
specific repositioning of transcription sites, and thus, chromosomal loci, within the interphase nucleus is a part of the
functional repertoire of the cell. Our data are not easily reconciled with a model by which DNA and the transcriptional machinery are anchored to a relatively rigid nuclear
scaffold or matrix during interphase. In addition, the observation from our fixed embryos of transcriptional loci
throughout the nuclear volume supports models of chromatin arrangement according to which transcription is not
restricted to the periphery of the nucleus or to a limited set of regions within the nucleus but rather occurs at a
large number of sites, perhaps close to the number of transcribed genes themselves, where simultaneous transcription
and processing take place. From these sites the packaged
mRNAs would then disperse throughout the nucleoplasm
and exit the nuclear membrane at unrestricted pores.
Finally, these in vivo studies in whole embryos indicate
that one can observe metabolic processes at specific gene
loci with specific probes and fast scanning CLSM. Further
studies could include dynamic inhibition of specific transcription, the observation of embryos with mutant enzymes for transcription or replication, and further studies
of the heat shock phenomenon.
). However, during gastrulation this orientation largely disappears, and homologous associations are formed (Foe and Alberts, 1983
; Campos-Ortega and Hartenstein, 1985
; Hiraoka et al., 1993
;
Dernburg et al., 1996
; Gemkow et al., 1996
). In many
other species or cell types one can observe only a territorial delineation with no defined polarity or homologous
pairing of the chromosomes (Cremer et al., 1994
).
). Certain
biochemical procedures lead to the isolation of a nuclear
scaffold or nuclear matrix (Lewis et al., 1984
). Experiments demonstrating and characterizing the components
of such scaffolds have led to ambiguous results (Dworetzky
et al., 1992
; Stuurman et al., 1992
; Kallajoki and Osborn,
1994
; He et al., 1995
; Mattern et al., 1996
). Unfortunately, existing data regarding the organization of transcriptional
complexes within the nucleus are conflicting, some data indicating preferential activity towards the nuclear periphery (Blobel, 1985
; Hutchison and Weintraub, 1985
) but
others showing a random distribution of sites throughout
the nucleus (Wansink et al., 1993
, 1994; Xing et al., 1993
).
As we have discussed previously (Buchenau et al., 1993
a),
many conflicts in the results concerning nuclear organization may be attributed to the use of different protocols for
staining in situ preparations of fixed cells. It is obvious that
it is not possible to make a linear extrapolation of data derived from the fixed state directly to the living organism.
An experimental strategy to study protein macromolecular assemblies in vivo may afford more direct insight into
nuclear processes. Just such an approach has been taken in
this investigation of the 93D transcriptional locus.
). The major hnRNPs of
Drosophila have been isolated and characterized (Matunis
et al., 1992a
). On polytene chromosomes of larval salivary
glands (Matunis et al., 1993
) some hnRNPs are abundant
molecules, present in many copies on most transcribed loci
where they possibly serve in some hnRNA packaging
function. In addition, specific minor components have
been identified by fractionation of Drosophila hnRNP
particles (Saumweber et al., 1980
; Risau et al., 1983
).
These proteins are also present in most of the transcriptionally active regions of polytene chromosomes but in an
amount estimated at only one to five protein molecules per transcript. One of these proteins, a 55-kD protein that
is specifically recognized by the monoclonal antibody Q18
(Saumweber et al., 1980
), has a strong sequence homology
to the mammalian hnRNP K family of proteins, and its
gene has been mapped on the 2R polytene chromosome to
the 57A region (B. Hovemann, personal communication).
Following a nomenclature introduced by Haynes et al.
(1990)
, we refer to the protein as hnRNA binding protein at region 57A or Hrb57A. This protein has been shown to
be present in some 100 transcriptionally active loci on larval salivary gland polytene chromosomes (Saumweber et
al., 1980
; Kabisch and Bautz, 1983
; Risau et al., 1983
) and
similarly, at active loci on chromosomes in other larval tissues with a lower degree of polytenization (H. Saumweber, unpublished observations). We describe in this paper
the distribution of this protein both in vivo and in situ at
high resolution in developing Drosophila embryos.
; Dangli
et al., 1983
). The heat shock locus 93D of Drosophila melanogaster contains the transcription unit heat shock RNA
omega (hsr-
; Garbe and Pardue, 1986
; Hovemann et al.,
1986
; Hogan et al., 1994
; Lakhotia and Sharma, 1995
). Two polyadenylated transcripts are produced by alternate
termination. The shorter
-c RNA is spliced and exported
from the nucleus. The
-n RNA is 8-18 kb long with no
known coding capacity and remains in the nucleus. The
93D locus is constitutively expressed in all cells and is
strongly induced upon heat shock (Bonner and Pardue,
1976
; Bendena et al., 1991
) or the application of certain chemicals (Lakhotia and Sharma, 1995
). It has been postulated that the 93D transcript serves as a docking site in the
assembly and stabilization of a number of important nuclear proteins for use immediately following recovery
from heat shock. Although we lack knowledge about a definitive biological function for the transcripts from the 93D
locus, their sequences provide us with an ideal system to
identify a specific transcriptionally active site in embryonic
nuclei. Similarly, we are able to take advantage of the redistribution of Hrb57A during heat shock so as to distinguish this transcriptional locus in all of the nuclei of the
embryo and follow its behavior in vivo. These studies illuminate facets of the transcription process and nuclear
structure in the Drosophila embryo and have implications
about the temporal and spatial constraints within interphase nuclei. To our knowledge, the results reported here
for the Hrb57A protein constitute the first direct in vivo observation of gene activation and repression brought
about by heat shock. We are able to follow the kinetics by
which the hnRNP K protein is recruited to the activated
93D locus in diploid cells from other chromosomal sites
after heat shock. Finally, we demonstrate that active transcription sites are mobile within nuclei, and that the formation and dissolution of these sites occurs in a time domain compatible with in vivo observations by fast confocal scanning microscopy. These dynamic observations corroborate the mobility of transcription sites described in an
earlier study (Buchenau et al., 1993
a) of the in vivo imaging of NonA, a protein component of active chromatin.
Materials and Methods
)
was used throughout. Flies were raised at room temperature on a medium
of cornmeal, agar, soy bean meal, malt extract, molasses, yeast, 0.5% (vol/
vol) propionic acid, and the mold inhibitor methyl p-hydroxybenzoate
(Caesar and Lorentz, Hilden, Germany).
). The antibody was purified from cell culture supernatants by chromatography on a protein A-Sepharose column
(Pharmacia, Freiburg, Germany) before use. For microinjection experiments the antibody was labeled for 2 h at a protein concentration of 0.6 mg/ml with a 15-fold molar excess of carboxytetramethylrhodamine-succinimidylester (TMrhodamine; Molecular Probes Inc., Eugene, OR) in carbonate buffer (pH 8.5) at room temperature. The reaction was quenched
with hydroxlamine, and the labeled antibodies were freed from unbound
dye by chromatography over Sephadex G25 in PBS. The antibodies were
concentrated by centrifugation in a microporus membrane, Centricon-10
(Amicon Corp., Danvers, MA). An absorbance spectrum of the final solution was taken, and the protein concentration and dye/protein labeling ratio were determined to be 0.54 mg/ml and 1.86, respectively. For indirect
immunofluorescence with the Q18 antibody we used a Cy3-coupled
(Fab)2 goat anti-mouse IgG (Jackson ImmunoResearch Labs, Inc., West
Grove, PA).
-n Transcript
-CA GTT GTT AAG ATA TAC CAT
ATA AAA AA (NH2)-3
, was synthesized on a DNA synthesizer (model 382A; Applied Biosystems, Foster City, CA) and purified by HPLC chromatography (Waters Millipore Corp., Milford, MA). The oligonucleotide was fluorescently labeled at a concentration of 1.5 mM with an eightfold
excess of carboxyfluorescein-succinimidylester (Molecular Probes Inc.) in
150 mM carbonate buffer (pH 9.3) at room temperature. After shaking
overnight, the reaction was stopped by addition of 100 mM Tris buffer and
the probe freed of unbound dye by repeated centrifugation over Centricon-3 (Amicon Corp.). The labeling ratio was 0.58 dye molecules per oligonucleotide.
).
).
. Stabilized chromosomes were denatured in 0.1 N NaOH (90 s at room temperature), washed in 2× SSC, dehydrated via increasing ethanol concentrations, and air dried. Hybridizations were performed using 7.5 ng labeled oligonucleotide in 5 µl 5× SSC under a sealed
coverslip at 50°C. After washing (5 min, 2× SSC, 2 min, PBS) the preparations were stained for DNA and mounted as above.
. Collected embryos of the appropriate stages were bleach dechlorionated in 50% hypochloride for 90 s and fixed in a heptane/buffer A/37% paraformaldehyde
mixture (9: 0.9: 0.1, by vol) for 20-40 min. Buffer A is 60 mM KCl, 15 mM
NaCl, 0.5 mM spermidine, 0.15 mM spermine, 2 mM EDTA, 0.5 mM
EGTA, 15 mM Pipes, pH 7.4. After removal of the water layer the embryos were devitellinized in a mixture of heptane/methanol (1:1) by vigorous shaking for 60 s and rehydrated through a methanol/buffer A series
(90, 75, 50, and 25% methanol) followed by extensive washing in buffer A
containing 0.05% Tween 20 in vol of 1 ml on a rotating wheel.
-n RNA were achieved with more stringent washing conditions as well
(0.5× SSC/Tween at 37°C).
a,b) using siliconized injection needles. After injection of 200-500 pl of the TMrhodamine-labeled mAb Q18 (0.54 mg/ml in the needle) the embryos
were oxygenated and incubated in a humid chamber before microscopic
analysis. Digital images of optical sections through living as well as fixed
embryos were collected using a confocal laser scanning microscope (LSM
310; Zeiss, Inc., Jena, Germany) and either a 40× NA 0.9 Plan-Neofluar
immersion objective equipped with a refractive index correction collar or a
63× NA 1.4 Plan-Neofluar oil immersion objective. Details about this system and the image acquisition have been described previously (Buchenau
et al., 1993
a).
Fig. 2.
Nuclear import and
mitotic distribution of
Hrb57A in living embryos.
A shows selected frames
from a time series of confocal images from a single blastoderm embryo during the nuclear cycles 11-14. The cycle
number is given at the bottom of each panel. M denotes
mitosis. Arrows indicate the
nonfluorescent mitotic chromatin (first panel) and a
weak accumulation of
Hrb57A in cycle 11 interphase nuclei (second panel).
(B) Plot of the mean nuclear fluorescence intensity measured in a single focal plane
for a series of images measured at 1 min intervals during cycle 13. An import of
Hrb57A is evident for the 10 min during interphase while
the sharp decline of fluorescence falls together with nuclear division. C and D are
time series of confocal images showing nuclear division in blastoderm (C) and
after gastrulation (D). I, interphase; M, metaphase; A,
anaphase. Arrows denote the
location of the dividing chromatin which contains a detectable amount of Hrb57A
after (D) but not before (C)
gastrulation. Bar, 10 µm.
[View Larger Versions of these Images (138 + 12K GIF file)]
Fig. 7.
Detection and mobility of the 93D locus in
vivo. Living embryos were
injected with rhodaminecoupled mAb Q18. After development at room temperature, embryos were heat
shocked at 37°C directly on
the stage of the microscope
to mark the 93D locus. (A) A
field of epidermal interphase
nuclei from an embryo 75 min after the beginning of
heat shock. (B) Time series
of 2-D projections of a single
amnioserosa nucleus from a
heat-shocked embryo during germ band elongation.
The original data set consisted of seven 1-µm Z-axis
sections per time point. The
schematic drawing in C
shows the location of the nucleolus (N) and the 93D loci
(a-d) within the nucleus in B. (D) A plot of the relative
minimal distances between
the loci of the nucleus in B
against time. The distances are given relative to the first
image of the series. (E) 10 two-body distance plots
against time demonstrating
the time-dependent changes in the distances between 93D
loci during heat shock. The
distances were measured
from 2-D projections of image stacks from seven different interphase nuclei in several embryos.
[View Larger Versions of these Images (56 + 18 + 14 + 32K GIF file)]
Results
) so as
to achieve a uniform distribution of the antibody within
the embryos. The in vivo distribution of the labeled mAb
Q18 was followed by CLSM, and the immunofluorescence of fixed embryos at similar time points was monitored as a
reference. The antibody injections as well as the irradiation of embryos during the observation had no discernible
detrimental effect on the further progress of embryogenesis. Similar viability between antibody injected and control
embryos has been documented in a previous study (Buchenau et al., 1993
a). Not only were microinjected embryos viable, but the antibody-antigen complex remained stable and shuttled between the nucleus and the cytoplasm faithfully at each nuclear division following the midblastoderm,
permitting us to follow the complex by CLSM for at least
seven cell cycles. Thus, the Hrb57A protein/Q18 mAb complex constitutes a tool for the direct in vivo observation of
transcriptionally active loci during early Drosophila development.
Fig. 1.
The distribution of
Hrb57A in fixed and living
embryos. The overall distribution of Hrb57A during
embryogenesis was observed in fixed embryos (A-C) using
indirect antibody staining or
followed directly in vivo by
microinjection of rhodaminecoupled mAb Q18 into living
embryos (D). (A) Preferential cytoplasmic localization of
Hrb57A, syncytial blastoderm,
nuclear cycle 13. (B) Nuclear localization, cellular blastoderm, cycle 14. (C) Hrb57A
is nuclear in all tissues during
later embryogenesis, as shown
here for an embryo of stage
10, at the time of full germ
band elongation. (D) The similar complete localization of
Hrb57A in late embryogenesis occurs in the microinjected embryos. Two optical
sections through a living embryo of stage 12 during germ
band retraction, showing the
in vivo labeling pattern of
Hrb57A. All images are single confocal sections.
[View Larger Version of this Image (85K GIF file)]
).
Fig. 3.
The 3-D intranuclear distribution of Hrb57A
in situ and in vivo. (A) Stereo
image showing the distribution in discrete loci of the
Hrb57A protein in a fixed interphase nucleus of a wholemount embryo reconstructed
from 25 optical sections with
a Z axis distance of 0.25 µm.
(B) Stereo image of a part of
a similar nucleus in a living
embryo, reconstructed from
6 optical sections separated by 0.4 µm. Both image stacks
have been recorded with a
Plan-neofluar oil immersion
objective 63×, NA 1.4, with a
0.14-mm coverslip. Bars, 2 µm.
[View Larger Version of this Image (118K GIF file)]
Fig. 4.
Fields of interphase nuclei in the amnioserosa of a fixed
(A) and a living (B) embryo during stage 11 (elongated germ
band) stained for Hrb57A. Both images are single confocal sections from stacks recorded as in Fig. 3. Width of the total field is
40 µm.
[View Larger Version of this Image (94K GIF file)]
). This locus is constitutively transcribed but
can be further induced by heat shock, both in salivary
glands (Bonner and Pardue, 1976
) and in embryos (Bendena et al., 1989
). We were interested to determine how
much of the Hrb57A is associated with 93D in normal embryos and after heat shock.
-end of the 93D transcript
-n (Hovemann et al., 1986
; Hogan et al., 1994
) was
synthesized and covalently labeled with fluorescein (Fig.
5 A). In squashed salivary gland chromosomes the labeled
oligonucleotide hybridized exclusively to the 93D region
both under conditions for DNA-DNA (data not shown)
and for DNA-RNA hybridization (Fig. 5, B and C), demonstrating the specificity of the probe and the constitutive
nature of the transcription from this locus. When formaldehyde fixed, whole-mount embryos were hybridized with
the probe to RNA, i.e., under nondenaturing conditions,
we detected one or two prominent spots per diploid nucleus with almost no labeling of the residual nuclear volume (Fig. 6 A). The polyploid nuclei of the embryo very
often contained more than two hybridization spots, indicating that in these cases the loci were not synapsed. The
fact that in all larval and embryonic tissues observed, the
number of transcript accumulations as revealed by the hybridization parallels the number of expected chromosomal 93D loci leads us to conclude that within the resolution of
the CLSM, our oligonucleotide probe reflects the location
of nascent transcripts at the 93D locus. Therefore it can be
used as a marker for the spatial location of this transcriptionally active gene in developing embryos. Fig. 6 A shows
a projection image of normal diploid nuclei from a region
of a fixed embryo hybridized to RNA (nondenaturing conditions) with the
-n probe and stained with mAb Q18 and
the merged multicolor image. These images have been reconstructed from the maximal intensities of 15 confocal sections for each fluorescence channel. A comparison of the
-n/93D signal (Fig. 6 A) and the corresponding Hrb57A
protein distribution in the merged panel indicates clearly
that the protein was constitutively associated with the transcripts at 93D in these nonheat shocked embryos. Fig. 6 B
contains a higher magnification image of two nuclei from the
field in Fig. 6 A. The shape and size of the hybridization signal correlated almost precisely with that of an intense
Q18 antibody binding region. In many but not in all nuclei
of nonstressed embryos, Hrb57A showed the highest concentration in the 93D region. To determine the relative
amount of the protein associated with 93D we measured
the fluorescence intensities of the anti-Hrb57A antibodies
in whole nuclei and in the nuclear subregion defined by
the
-n probe. Scoring many nuclei in several embryos, we
found 2-5% of the total nuclear Hrb57A protein was associated with the 93D locus in normally developing embryos.
Fig. 5.
Transcripts from the 93D
region and detection of the locus by
oligonucleotide hybridization. (A)
Schematic representation of the
transcripts from the heat shock
RNA- region in 93D. The gray
box indicates the location of the intron which is spliced out of the
smaller
-c RNA. The repeat region of the long
-n transcript is
shown in black. The sequence of
the fluorescently labeled oligonucleotide, Fl-P2, used as a probe for
-n is given below a 29 base transcript sequence which is strongly
conserved between the tandem repeats. B and C demonstrate that the
probe specifically binds to 93D
RNA in squashed polytene chromosomes. (B) DNA stained with
DAPI. (C) 93D hybridized with FlP2 under nondenaturing conditions.
[View Larger Versions of these Images (48 + 14K GIF file)]
Fig. 6.
Association of Hrb57A with the 93D locus in situ. The RNA at the 93D locus in the nuclei of fixed embryos was detected by hybridization with the Fl-P2 oligonucleotide (left column) and the Hrb57A protein by mAb Q18 followed by a Cy3-coupled secondary antibody (center column). The superposition of both signals in an RGB image generates a yellow color where 93D and the protein are
colocalized (right column). (A) A group of interphase nuclei from a nonstressed embryo. Overlay of 15 optical sections separated by
0.35 µm. (B) Higher magnification of a subregion from the field shown in A demonstrating the precise overlap of the 93D signals with
some of the Hrb57A accumulations. (C) A group of interphase nuclei from an embryo that had been heat shocked at 37°C for 60 min before fixation. The restriction of Hrb57A to the 93D locus is evident.
[View Larger Version of this Image (47K GIF file)]
-n and the progressive restriction of the protein to 93D was dependent on the age
of the embryos. As expected, embryos of the preblastoderm stage did not show any reaction due to the lack of
transcriptional activity. After gastrulation the response to
the stress situation was unambiguous but progressively stronger in older embryos. The disappearance of Hrb57A
from most of the nuclear volume and its concentration on
the 93D locus under heat shock conditions parallels exactly the redistribution of the protein in polytene nuclei after heat shock (Dangli and Bautz, 1983
).
Fig. 8.
Dynamic changes in the intranuclear distribution of Hrb57A during recovery from heat shock. Stereo images of amnioserosa nuclei reconstructed from five optical sections separated by 2 µm. Intranuclear accumulations of Hrb57A are numbered (see text). (A) 6 min after reducing the temperature to 25°C. (B) 10 min into recovery. Bar, 5 µm.
[View Larger Version of this Image (73K GIF file)]
Discussion
) and localized to a number of transcription sites
on salivary gland polytene chromosomes from third instar larvae (Dangli and Bautz, 1983
). A partial cDNA sequence
of the gene has been determined and localized to region
57A on squashed polytene chromosomes (Hovemann, B.,
personal communication). The amino acid sequence derived from this nucleotide sequence reveals several glycine-rich regions, a K-homology domain, as well as other
sequence motifs which have been found in hnRNP K proteins of other species and other RNA-binding proteins
(Hovemann, B., personal communication). In vitro binding studies with other hnRNP K proteins have suggested
that at least one mode of binding for this class of proteins
is through polyC-rich sequences in RNA transcripts (Matunis et al., 1992b
; Dreyfuss et al., 1993
; Leffers et al., 1995
).
Recent in vitro experiments demonstrate that hnRNP K
acts as a transcription factor, activating genes containing CT elements (Michelotti et al., 1996
). Our studies demonstrated a 1:1 correspondence between the shape of the
protein immunofluorescence and the fluorescent oligonucleotide in situ hybridization signal on the
-n transcript at
the 93D locus (Fig. 6). The tandem repeats in the
-n transcript from the 93D locus are, however, very AT rich. The
only part of the sequence with long stretches of polyC is in
the 5
end, contained also in the shorter
-c transcript (Garbe et al., 1986
). It is possible that the binding of the
Hrb57A protein to the transcript is mediated through this
region and that the repeat sequences are primarily involved in secondary or tertiary structure which facilitate
the localization or stabilization of the RNA at the site of
transcription.
). It
is possible that the interphase chromosome structure in
vivo is less compacted than after fixation and that a microscopically visible higher order structure of fixed chromatin
is partly the result of precipitation artifacts. Support for
this view comes from comparing electron microscopic images of cells conventionally prepared by fixation and dehydration with nonfixed, vitrified mammalian cells observed
at
160°C. Such rapidly frozen cells with their fully hydrated interphase chromosomes lack any obvious chromatin organization above ~11 nm (Dubochet, 1995
). A second, alternative explanation for the differences observed in our study is the possible existence of a nucleoplasmic
fraction of the Q18-antigen complex that is not tightly associated with transcription sites or RNA in vivo. This fraction might be less efficiently cross linked during fixation
and therefore differentially extracted by the fixative solutions. After fixation, the remaining protein complex, Q18-
Hrb57A-RNP, would then appear as discrete fluorescent
loci in a darker, protein-free background. Support for this
interpretation is provided by the change in the protein distribution from the "living" to the "fixed" pattern upon fixation of microinjected embryos and by the fact that we observe nuclear localization of Hrb57A in living embryos
two cell cycles earlier (cycles 11 and 12) than in fixed preparations (Figs. 1 and 2). Since only a very limited set of
genes is transcribed during these early nuclear cycles, it is
possible that the bulk of the intranuclear Hrb57A is not
yet associated with transcript or transcribing genes and, in
line with the argument presented above, would be more easily extracted during fixation. A third explanation for
our results relates to the dynamic behavior of transcriptional sites, which we have documented in in vivo temporal studies, examples of which are shown in Figs. 7 and 8.
Our observations indicate that the chromatin-associated
transcription sites in a living nucleus undergo dynamic rearrangements, suggesting great flexibility in the chromatin. Microscopic movements, in a time domain below or
comparable to the temporal resolution of the microscope,
could lead to a more homogeneous intensity distribution
of fluorescence and to an increase in the apparent size of
areas of protein concentration in in vivo images by the
convolution of a spatial pattern with dynamic temporal
changes. At present it is not possible to determine which
of these explanations accounts for the differential distribution of Hrb57A, and presumably other RNA associated
proteins, within the living nucleus.
; Segalat and Lepesant, 1992
), Hrb57A is excluded from the nucleus until the onset of zygotic transcription. Our in vivo studies in blastoderm embryos allowed a direct observation of the kinetics of nuclear import
of Hrb57A (Fig. 2). During the interphases of these early cycles the intranuclear concentration of the protein increased almost linearly. In contrast, the kinetics of the export of
the hnRNP from the nucleus at mitosis was very rapid. The
fact that Hrb57A is continuously imported throughout
most of the interphase period in early embryogenesis suggests that the protein might require the assembly of active
transcription before nuclear transport. However, a similar
kinetics of nuclear import was observed for the transcription-associated protein, NonA (Buchenau et al., 1993
a, 1996). This protein is still transported in the presence of
the RNA polymerase II inhibitor
-amanitin. We are presently investigating the behavior of Hrb57A under these
conditions.
have shown that the Hrb57A protein is almost exclusively localized in the puff at 93D of heat
shocked third instar larvae. The experiments described
here clearly demonstrate that this phenomenon also occurs in embryos and therefore indicate that it might reflect
an important and basic function of the 93D transcript. Transcription of this locus and its influence on other heat shock
loci have been studied in some detail (Garbe and Pardue, 1986
; Hovemann et al., 1986
; Bendena et al., 1991
; Vazquez
et al., 1993
; Hogan et al., 1994
; Sharma and Lakhotia, 1995
;
Lakhotia and Sharma, 1995
). Since a variety of proteins
concentrate at the 93D locus upon heat shock, for example, Hrb87F (Haynes et al., 1991
; Hovemann et al., 1991
)
and the heat shock protein HSP90 (Morcillo et al., 1993
), it
has been proposed that the
-n transcript fulfills a storage
function for the sequestration and protection of transcription factors and other nuclear proteins during heat shock
(Hogan et al., 1995
). However, the fact that its transcription is modulated in nonheat shock conditions (Bendena
et al., 1991
) suggests that it could also serve as a sink for
these proteins when they are not actively engaged in transcription or mRNA processing. Our in vivo observations
support this hypothesis. During heat shock and the termination of transcription at most nuclear loci, we measured
Hrb57A redistribution leading to the accumulation of
>50% of the protein at the 93D locus, as opposed to the
disappearance of the protein from the nucleus under these
conditions (Figs. 6 and 7 A). After heat shock, during the
early stages of recovery, there is obvious retrograde redistribution and appearance of new protein loci throughout
the nuclear volume (Fig. 8), presumably representing reinitiated transcriptional loci.
a; de Boni, 1994). Most
of the models for nuclear architecture are derived, on the
other hand, from experiments performed on fixed cells or in vitro preparations of nuclear extracts. An interesting
model by which transcription might occur in the interchromosomal space on the periphery of the chromosome territories is derived from observations of fluorescence in situ
hybridization of chromosome DNA sequence libraries,
transcript labeling, and antibody staining for snRNPs (Zirbel et al., 1993
; Cremer et al., 1994
). The extensive literature on models involving the coupling of transcription to a
nuclear matrix whereby the "RNA polymerases are immobilized onto the nuclear matrix structure and DNA reels
through the immobilized transcription complexes" has been
reviewed recently by van Driel et al. (1995).
) or of centrosomal regions after induction of gene expression (Park and de Boni, 1992; Sahlas et al., 1993
; Spector et al., 1994
; Janevski et al., 1995
) have been inferred
from the analysis of fixed cultured cells. We previously
suggested that transcriptional loci could move rapidly about
the nucleus from the in vivo distribution of a transcription associated protein (Buchenau et al., 1993
a).
). We were able to
follow this return to normal transcription by direct observation of the microinjected, heat shocked embryos. The
reduced binding of Hrb57A at the 93D locus as well as the
appearance of new protein accumulations are obvious. A
typical redistribution over a period of only 4 min early
during this recovery process is documented in Fig. 8.
Received for publication 30 August 1996 and in revised form 7 February 1997.
Please address all correspondence to Donna Arndt-Jovin, Department of Molecular Biology, Max Planck Institute for Biophysical Chemistry, 370170 Gottingen, Germany. Tel.: (49) 551-2011-393; Fax.: (49) 551-2011467; E-mail: djovin{at}mpc186.mpibpc.gwdg.deWe thank Dr. B. Hovemann for making unpublished data on the sequence and localization of the partial cDNA clone for Hrb57A available to us.
CLSM, confocal laser scanning microscopy; hn, heterogeneous nuclear; 3-D, three dimensional; sn, small nuclear.