* Graduate Group in Biophysics and Department of Biochemistry and Biophysics, University of California, San Francisco,
California 94143-0554; and
The Howard Hughes Medical Institute, San Franciso, California 94143
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Abstract |
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The dynamics by which homologous chromosomes pair is currently unknown. Here, we use fluorescence in situ hybridization in combination with three-dimensional optical microscopy to show that homologous pairing of the somatic chromosome arm 2L in Drosophila occurs by independent initiation of pairing at discrete loci rather than by a processive zippering of sites along the length of chromosome. By evaluating the pairing frequencies of 11 loci on chromosome arm 2L over several timepoints during Drosophila embryonic development, we show that all 11 loci are paired very early in Drosophila development, within 13 h after egg deposition. To elucidate whether such pairing occurs by directed or undirected motion, we analyzed the pairing kinetics of histone loci during nuclear cycle 14. By measuring changes of nuclear length and correlating these changes with progression of time during cycle 14, we were able to express the pairing frequency and distance between homologous loci as a function of time. Comparing the experimentally determined dynamics of pairing to simulations based on previously proposed models of pairing motion, we show that the observed pairing kinetics are most consistent with a constrained random walk model and not consistent with a directed motion model. Thus, we conclude that simple random contacts through diffusion could suffice to allow pairing of homologous sites.
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Introduction |
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IN eukaryotes, a chromosome is sometimes aligned and
associated with its homologue over part or all of its
length. Although this chromosome alignment is prominent in meiosis (Roeder, 1995), for some organisms such
as Dipteran insects, this association, termed homologous
chromosome pairing, is observed to be a normal part of
nuclear organization (Metz, 1916
). Although in other organisms, less extensive homologous pairing is seen (e.g.,
Vourc'h et al., 1993
; Lewis et al., 1993
). Nevertheless, a
number of intriguing biological phenomena center around
homologous chromosome pairing.
Pairing of homologous chromosomes can also influence
gene regulation. In Drosophila melanogaster, gene expression can be modulated by physical pairing of homologous
loci in what are termed transvection and trans-sensing effects (reviewed in Tartof and Henikoff, 1991). Similar effects have been reported in such widely divergent organisms as Antirrhinum majus (Bollman et al., 1991) and
Neurospora crassa (Aramayo and Metzenberg, 1996
). In
these cases, either suppression or enhancement of a phenotype is observed when pairing is disrupted by chromosomal rearrangements. In cases where it has been explicitly tested (e.g., Goldsborough and Kornberg, 1996
), the
effects can be accounted for by changes in levels of transcription that accompany the disruption of pairing. Another area where homologous pairing might play an important role is in paramutation, an interaction between
alleles that leads to a directed heritable change at a locus
at high frequency (Patterson and Chandler, 1995
). Similarly, methylation transfer, believed to be important for
many epigenetic phenomena, seems to require pairing of
homologues as an initial and crucial step in the process
(Colot et al., 1996
).
Although progress is being made in determining the biological relevance of homologous pairing, relatively little is
known about the mechanism by which homologues become paired. For both somatic and meiotic homologous
pairing, this is primarily a consequence of the inability to
directly monitor two homologous sites as pairing proceeds.
Thus, many fundamental questions about the dynamics of
how homologous chromosomes come together remain unanswered. Is the homology search carried out by discrete
sites or simultaneously along the entire length of the chromosome? How do those sites that undergo homology
search locate each other in the nucleus? Once homologous
sites have located each other, does the pairing of adjacent
sites proceed processively? Furthermore, numerous models have been put forth for how this pairing might take
place (as reviewed in Loidl, 1990). In general, these models can be characterized as those emphasizing active movement of chromatin to bring homologous regions into contact or those relying mainly on fortuitous encounters of
homologous sites brought about by random movements of
the chromatin by diffusion (also referred to here as random walk motion). Further complicating this issue is what
role, if any, does nuclear organization play in facilitating the homology search. This question has been raised by numerous meiotic studies suggesting that prealignment through
bouquet formation (an alignment of telomeres and chromosomes within meiotic nuclei; reviewed in Dernburg et
al., 1995
; Scherthan, 1996), Rabl orientation (a centromere
to telomere polarity found in interphase nuclei; Rabl,
1865; Fussell, 1987
) or juxtaposition of chromosomes during metaphase congression (Maguire, 1983a
) can reduce
the volume over which homology search takes place and is
thus a necessary part in the meiotic pairing process. In this
report, we attempt to address these questions and related
ones by following the kinetics of somatic homologue pairing in Drosophila embryos.
Drosophila melanogaster offers a unique system in which
to study homologous pairing. Drosophila chromosomes
are thought to be homologously associated in the early
stages of development in addition to their association
observed during meiosis. For instance, the giant polytene
chromosomes found in larval tissue exhibit a close synapsis of homologues along their entire lengths. Observations
of a side-by-side juxtaposition of metaphase chromosomes in squashed neuroblast preparations lend further support
that homologues pair early in development in this organism (Metz, 1916). Furthermore, examination of homologous pairing during embryogenesis of a single site has indicated that the attainment of homologous pairing for
Drosophila as determined by the pairing of the histone locus occurs very early (Hiraoka et al., 1993
).
There are several advantages for studying the dynamics of homologue pairing during the well-characterized stages of embryonic development (reviewed in Foe, 1993). Between the 10-13th nuclear cycles, nuclei divide in tight synchrony every 10-17 min as a monolayer at the embryo surface. At cycle 14, interphase increases in duration and is followed by a patterned mitosis where patches of cells enter mitosis at different points in time. Up until gastrulation, about an hour into cycle 14, the embryo exists as a cellular blastoderm such that cells continue to be arrayed as a monolayer at the surface of the embryo (see Fig. 1). So within one embryo, a synchronous population of nuclei in a defined orientation is available for statistical analysis of pairing events. After cycle 14, most cells, unlike at earlier stages, have defined cell fates and undergo two more cell cycles, again with patterned mitoses, ending with a terminal interphase at cycle 16. Imaginal discs and neuroblasts are the exceptions; the former undergoes one more cell division and the latter several cycles more. Although nuclei no longer behave identically at these later developmental stages, analysis of how pairing changes between the differentiated groups of cells can give us information on what factors influence a chromosome's ability to pair. Also aiding in the pairing analysis is that the embryonic developmental stages described here are all extremely amenable to the three-dimensional (3-D)1 imaging techniques needed to properly observe the pairing. Particularly useful is that many of these nuclear cycles can be imaged as they proceed in vivo, which is important for developing time courses necessary for determining the mechanisms governing the homology search.
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To elucidate how pairing proceeds during Drosophila development, we used fluorescence in situ hybridization (FISH) and immunofluorescence under conditions that preserve nuclear and chromosomes substructure combined with high resolution 3-D optical microscopy. The pairing frequencies of 11 loci distributed over chromosome arm 2L were evaluated at several timepoints during Drosophila development. This analysis revealed that all 11 loci are paired within 13 h after egg deposition (AED), demonstrating that pairing along the entire length of the chromosome is attained very early in the Drosophila life cycle. More crucially, the frequencies of pairing at different sites indicates that side-by-side alignment is achieved through the independent initiation of pairing at discrete loci rather than by a processive zippering of sites along the length of chromosome.
We measured the time course of pairing of the histone locus through a cycle of interphase and compared our observations to computer simulations of pairing based upon different models of chromosome motion. Through quantitative kinetic analyses, we provide evidence that simple random contacts through diffusion are sufficient to allow pairing of homologous sites at the observed rates.
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Materials and Methods |
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Drosophila Stocks
Wild-type flies were obtained from an Oregon-R stock maintained at
UCSF. The lt×13 stock (Wakimoto and Hearn, 1990) was provided by B. Wakimoto (University of Washington, Seattle, WA). All stocks were
maintained at 24°C.
Preparation of DNA Probes
Probes were prepared as described in Hiraoka et al. (1993) for the histone
gene clone, in Dernburg et al. (1996)
for the synthetic oligonucleotides
(AATAG, AACAC) used to detect heterochromatic repeats, and in Marshall et al. (1996)
for the P1 genomic clones. The plasmid containing the
4.8-kb HindIII fragment of Drosophila melanogaster histone genes (Lifton
et al., 1977
) was kindly donated by G. Karpen (Salk Institute, La Jolla,
CA). The Responder (Rsp) probe was a gift from C.I. Wu (University of
Chicago, IL). The P1 clones (Hartl et al., 1994
) 32-95 (DS03071), 14-92 (DS01340), 16-89 (DS01529), 2-82 (DS00178), 44-63 (DS0419), 9-93 (DS00436), and 96-45 (DS09165) were obtained from the Berkeley Drosophila Genome Project. Based on salivary chromosome maps (Heino et
al., 1994
), the approximate distance in megabases between probes 32-94, 14-92, 16-89, 2-82, 44-63, 9-93, histone, and 96-45 are 1.8, 3.9, 4.4, 1.1, 1.1, 3.4, and 0.2 Mb. The labeling procedure, used for the histone gene clone,
the oligonucleotides and the P1 clones was carried out exactly as described in Dernburg and Sedat (1997)
. Probe DNA (except for oligos) was
first amplified using degenerate oligonucleotide-primed polymerase chain
reaction. Four-base cutting restriction enzymes were then used to digest
the DNA before end-labeling with either rhodamine-4-dUTP (FluoroRed; Amersham Corp., Arlington Heights, IL) or digoxigenin-dUTP
(histone and oligos only) in a terminal transferase (Ratliff Biochemical,
Los Alamos, NM) reaction. In some cases, fluorescein-12-dUTP (Renaissance Inc., Boston, MA) was used instead of the other fluorescent labels.
Confidence in the FISH Signal
To be confident that the observed FISH spots actually represent hybridization to the paired or unpaired location of a particular site, probes were
selected or tested for unique localization. The heterochromatic sites used
in this study have been previously mapped and are found mainly on chromosome 2 (Lohe et al., 1993) except for AATAG. Since AATAG satellite
sequences are also found on the Y chromosome, a chromosome Y-specific
probe was used to identify male embryos to exclude them from this study.
The sequence AATAG was also found to a small extent on chromosome
4, however, we were able to identify the more major FISH spots corresponding to the AATAG sites on chromosome 2. To ensure that euchromatic probes made from the P1 clones also marked unique sites, neighboring clones 80 kb away were labeled with a different fluorophore and simultaneously observed with the corresponding probe to establish whether similar regions of localization could be found (data not shown). Only probes
meeting this criteria were used for the subsequent pairing experiments.
Preparation of Embryos and Wing Discs
To obtain embryos in cycle 13 and early cycle 14, embryos were collected
for 1 h and aged for 1.83 h before fixation. For the 4-, 6-, and 13-h timepoints, collection was set for 1 h with 3.5-, 5.5-, and 12.5-h aging periods,
respectively, at 24°C. Embryos were then bleach dechorionated, fixed in
3.7% formaldehyde, and devitellinized as described by Hiraoka et al.
(1993). FISH was performed using a method reported in Dernburg et al.
(1996)
. To clearly delineate the nuclear boundaries, anti-Drosophila lamin monoclonal T40 was added and detected using either fluorescein or Cy5-conjugated goat anti-mouse secondary antibodies (Jackson ImmunoResearch Laboratories, Inc., West Grove, PA; Paddy et al. 1990
). Before imaging, embryos were stained with 0.5 µg/ml DAPI in 50 mM Tris-Cl for 10 min and mounted on no. 1.5 coverslips coated with 1% poly-L-lysine to aid
in embryo adherence. Most of the buffer was removed and a Vectashield
antifade mounting medium (Vector Laboratories, Inc., Burlingame, CA)
was applied to the embryos before sealing the coverslip to the slide with nail polish.
Wing discs were dissected from climbing third instar larvae in Robb's
saline (Ashburner, 1989). The wing discs were then transferred to a hypotonic 0.7% Na citrate solution for 5-10 min and then to 45% acetic acid on
a 18 × 18, no. 1.5 siliconized coverslip for 3 min. Samples were then
squashed by inverting a slide over the coverslip and applying pressure.
The slide was immediately transferred to 100% methanol after popping
the coverslip off in liquid nitrogen. Hybridization was performed as described by Pardue (1986)
.
3-D, Multi-Wavelength, Fluorescence Microscopy
3-D datasets were acquired with a scientific-grade cooled CCD camera
(Photometrics, Tucson, AZ) attached to an Olympus IMT-2 inverted fluorescence microscope. Action of the shutters, filter combinations, stage
movement, and data collection were under the control of the Resolve3D
data collection program (Chen et al., 1996) developed for use on an Indy
workstation (Silicon Graphics, Sunnyvale, CA). A 60× 1.4 NA Olympus
lens (0.1117 × 0.1117 pixel size in the xy-plane) and n = 1.5180 immersion
oil (Cargille Laboratories, Cedar Grove, NJ) was used to image 512 × 512 pixel fields of 40-130 embryonic nuclei. Early cell cycle stages of the embryos were determined by the number of nuclei in a 512 × 512 pixel image. Each image of a 3-D stack was acquired by moving the stage in 0.5-µm
intervals. For every focal position, an image was taken for each of the
wavelengths corresponding to the fluorophores used in the experiment.
After collection, data stacks were corrected for fluorescence bleaching
and deconvolved with experimentally determined point spread functions
using a constrained iterative deconvolution method (Agard et al., 1989
).
The wing disc squashes were collected as multiwavelength 2-D images at a
single focal plane.
Analysis of Lamin and FISH Signals
The lamin signal was used to delineate the boundary of each nucleus. An
outline of the lamin signal for each focal plane of the nucleus was determined by using a function that creates 2-D polygons to represent the outline. Each 2-D polygon was created semiautomatically by manually placing a seed point somewhere internal to the lamin; from this point an
automatic search for the internal edge of the lamin extending radially outward from the seed point was initiated. A percentage change of intensity
relative to the seed point was used to evaluate whether each encountered
pixel was at the edge of the lamin signal. The actual outline pixel, selected
to be at the middle of the lamin signal, was obtained by extending the location of the pixel to be a fixed distance from the determined edge. All the
pixels belonging to a nucleus were obtained by grouping together all 2-D
polygons with the greatest z-axis overlap. Once a set of outline points belonging to a nucleus was determined, a surface harmonic expansion was
used to fit a surface to each nucleus as described in Marshall et al. (1996).
The 3-D location of each paired or unpaired FISH spot was obtained by first interactively picking a point in the vicinity of the FISH spot in each nucleus. Note that only nuclei with signals of distinct size and intensity were examined. The average signal sizes during cycle 14 for a P1 probe were 0.40 µm unpaired and 0.58 µm paired and for a histone probe were 0.54 µm unpaired and 0.62 µm paired. From that picked point, an automatic search for the maximum intensity pixel was made in an area specified by a given xy- and z-range. The 3-D location was further refined by calculating the intensity-weighted center of mass coordinates for that spot. Each FISH spot was then assigned to the nucleus whose surface enclosed it. At this point, its 3-D location was converted into the coordinate system of its assigned nucleus.
Determination of Progression in Cycle 14 Interphase from Nuclear Elongation
Embryos were bleach-dechorionated and injected at midlength as generally described in Minden (1989). 40,000 mol wt fluorescein dextran (Molecular Probes, Inc., Eugene, OR) was injected at a concentration of 2 mg/ml.
Time-lapse, 3-D data stacks of embryonic nuclei starting from mid-cycle
13 interphase to mid-cycle 14 interphase were collected with our CCD-based 3-D wide-field fluorescence microscope. Using a 0.2-s exposure
time, the living embryos were imaged using the same lens and oil configuration as for the hybridized embryos. The average nuclear length was obtained by measuring the top and the bottom of the nuclear volumes created by the excluded dextran. A least-squares analysis of nuclear length as
a function of time determined a best-fit second degree polynomial with an R2 value of 0.9188. Using the equation from the fit, 0.0044t2 + 0.4371t + (4.0754
ht) = 0 where t = time and ht = nuclear length, the time of progression for any cycle 14 embryo for the first 50 min of cycle 14 interphase
was determined from knowledge of average height of the nuclei for that
embryo.
Simulations
Diffusive motion was simulated using a random walk on a cubic lattice
(Kao and Verkman, 1994). The average size of unpaired FISH signals was
used for the size of the particles representing the unpaired loci. For each
run, pairs of particles were initialized to positions reflecting the initial distribution of the site obtained from the experimentally measured average
radial and vertical positions, < ro > and < zo > and their respective standard deviations,
ro and
zo. A normal distribution of the particles was
generated using these measured values as a starting point for the simulation. A 3-D random walk for each pair of particles was then simulated. Each iteration of the simulation represented a small time step of
= 50 ms. At each step, the x, y, and z coordinates were incremented and decremented with equal probability by an amount
= 2D
, where D is the diffusion coefficient. Spatial constraints were imposed on the entire random
walk by limiting motion within a cylindrical volume specified by a radial
boundary and a vertical boundary. To measure the potential range of radial and vertical positions, we measured the average radial and vertical
positions < r > and < z > along with their standard deviations,
r and
z
over the duration of pairing. The radial and vertical boundaries were then taken as < r > +
r and < z > ±
z. Also at each step, the pairing state
and the distance between unpaired particles were calculated. Two particles were considered paired if the distance between them was less than the
diameter of an particle. In these simulations, once two particles become
paired, they remain paired. The results from the pairing evaluations were
recorded every 20 s of the simulation. 1,000 such runs were carried out for
each simulation and the results pooled to obtain the profiles of the overall
pairing frequency and average inter-homologue distance as a function of
time.
To simulate a directed motion model with constant velocity, the same
initial conditions, boundaries, and pairing evaluations used in the random
walk simulations were used. However, at each step, the positions of the
two points were moved directly towards each other by an amount = v
,
where v is the velocity.
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Results |
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Different Sites Along a Chromosome Arm Show Distinct Pairing Dynamics
To characterize how pairing initiates for a large chromosomal region, we hybridized probes to a series of sites
spanning chromosome arm 2L at several timepoints in
Drosophila development. We chose to focus on chromosome arm 2L since the pairing for one locus, the histone
gene cluster, had previously been determined (Hiraoka et al.,
1993) and could be compared with the pairing of other sites. FISH probes were made as described in Dernburg
et al. (1996)
to eight sites spanning 2L, each no more than
five polytene divisions apart, and to three sites in the heterochromatin. Probes to both euchromatic and heterochromatic sites were chosen to detect any differences in
pairing that might be associated with the different chromatin states. Fig. 2 A diagrams the probes and their positions along 2L.
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Embryos at several different developmental stages (2.0 [cycle 13], 2.3 [cycle 14], 4, 6, and 13 hours AED and wing discs dissected from climbing third instar larvae) were fixed and then hybridized with one or two FISH probes (see Materials and Methods). After hybridization, both embryos and wing discs were stained with antibodies to the nuclear lamin to delineate the nuclear volume. This marker was particularly useful at later stages of development when nuclei are generally smaller, more densely packed, and irregularly shaped. To confine our pairing observations to interphase nuclei, nuclei were counterstained with DAPI.
3-D images of hybridized nuclei were recorded using a
wide field deconvolution optical microscope (Hiraoka et al.,
1991) except in the case of the squashed wing disc preparations where 2-D images were collected. Fig. 2 B shows a
representative focal series of optical sections collected
from nuclei of an embryo at cycle 14. Signals corresponding to two FISH probes, the anti-lamin antibody (Fig. 2 B,
middle right) and DAPI (far right) were recorded. Examination of the full 3-D nuclear volume showed that each interphase nucleus generally contained one or two FISH signals of similar size and shape that are interpreted to be the
paired and unpaired homologous loci, respectively. A site
was defined as paired if only one signal at twice the intensity of the unpaired locus was seen or if the 3-D distance
between two signals was less than the diameter of the hybridization spot. By counting the percentage of nuclei with paired FISH signals, a pairing frequency for each of the
probes was determined at different timepoints of development. The cumulative result for all the probes is shown in
Fig. 3 and Table I. To visualize the spatial/temporal patterns of pairing throughout development, the pairing frequencies for the different probes for each of the selected
times were plotted as a 3-D surface map.
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Fig. 3 illustrates that all sites eventually pair during embryonic development but the timing of the initiation of pairing is specific to each individual locus. Between 6 and 13 h of development, all sites attain pairing levels of >60%, much greater than the low level of pairing (~10%) seen early in development at cycle 13 for many of the sites. This increase in pairing levels continues into the larval stage (wing discs) where >95% of the nuclei contain paired loci. We note that at some time intervals, pairing at some loci appears to decrease slightly, but this is a minor effect and such sites ultimately achieve high levels of pairing. From this data it is clear that there is a significant variation in the attainment of pairing for different chromosomal sites. Of the 11 loci examined, the histone locus was observed to pair first (61% paired at cycle 13), followed by the Rsp heterochromatic locus (85% at cycle 14). By contrast, significant levels of pairing for other sites were often only seen after 6 hours of development indicating that pairing was attained considerably later for these sites.
We looked for general trends in pairing over the whole
chromosome arm (Fig. 3). Previously, it has been proposed that pairing might occur through a zippering process
originating at one site that would then spread processively
down the chromosome arm (Lewis, 1954; Smolik-Utlaut
and Gelbart, 1987
; Hiraoka et al., 1993
). If this were true,
sites closer to the single initiation point should exhibit
higher levels of pairing than those farther away, with pairing levels falling off with increasing distance from the origin. However, such a spreading phenomenon is inconsistent with our observation that during cycle 14 the histone
and Rsp loci both attain higher levels of pairing than the
intervening AATAG locus. Moreover, when the pairing
state of two different loci are compared within the same
nucleus by carrying out double-label FISH to visualize the
two loci separately, we found that pairing at histone was
statistically independent of pairing at 9-93 (according to a
standard 2 × 2 contingency table test (Zar, 1984
; P 61-65),
2 = 0.00014, indicating that the correlation in pairing between the two sites considered is insignificant even at the
0.5 confidence level). This independent pairing of different sites on the same chromosome arm within the same
nuclei is not consistent with processive spreading and
rather suggests that pairing can occur at multiple independent sites along the chromosome arm.
Another possibility for the early attainment of high levels of pairing for some sites may be that repetitive loci
have some preferential pairing ability because of the
greater probability that a single repeat would find a
matching site. Both the histone and Rsp loci, the two sites
that pair the earliest, consist of several repeated sequences
(Lifton et al., 1977; Lohe et al., 1993
). However, examination of other repetitive probes such as the satellite sequences AATAG and AACAC, both of which show low levels of pairing at a time when both histone and Rsp show
high levels of pairing, provide direct evidence that the
number of repeats in a locus is not the dominant factor in
the early attainment of homologous pairing.
Cells Following Different Developmental Paths Show Equivalent Pairing Levels
In later stages of embryogenesis, the initially homogeneous cell population divides into diverse cell groups, each following different developmental paths. Hence, the possibility that pairing levels could vary between each subpopulation of nuclei. We first tested whether any difference could be observed in pairing levels between nuclei destined for germline and somatic lineages. Starting at cycle 9, cells fated to form the germline (pole cells) separate from the main body of nuclei. These pole cells begin protein synthesis early and divide two more times on their own schedule. Comparison of the pairing levels from pole cell nuclei (53%, n = 19) and the main body of nuclei (60%, n = 44) for the histone locus obtained from the same cycle 14 embryo did not reveal a significant variation in pairing frequency between the two types of nuclei. In fact, the observed variation fell within the normal range found between separate internal groups of synchronized blastoderm nuclei. For instance, when four randomly chosen regions of nuclei from the same early cycle 14 embryo were examined for their levels of pairing, pairing frequencies of 39% (n = 100), 36% (n = 117), 46% (n = 118), and 40% (n = 107) were observed. This shows that a 10% range in pairing levels is within the normal fluctuation expected for measurements between synchronized populations. Similarly, no large differences were found in the pairing frequencies of the P1 09-93 locus between nuclei within the ectoderm (25%, n = 44) and mesoderm (27%, n = 26) germ layers in a 6-h AED embryo. This was particularly surprising since the size and morphology of the nuclei differed greatly between the two layers: ectoderm nuclei are columnar with an average volume of 43 µm3 whereas the mesoderm nuclei are squamous with an average volume of 69 µm3, a 60% increase in volume over the ectoderm nuclei. Therefore, at least in these cases, pairing was not affected by changes related to cell differentiation.
Pairing Does Not Require Targeting Loci to Special Regions within the Nucleus
We then wished to determine whether the position of a
site in the nucleus has any influence on pairing. For example, there might be specific territories in the nucleus, such
as near or on the nuclear envelope, where pairing preferentially takes place. Recently, it has been shown in Drosophila embryos that different loci reproducibly occupy
different discrete regions within the nucleus (Marshall et
al., 1996). Moreover, a set of loci have been identified that
associate specifically with the nuclear envelope, whereas
other loci are localized to a distinct internal subregion. Furthermore, theoretical considerations of how pairing
could be optimized suggest that by limiting the homology
search to regions adjacent to the nuclear envelope would
reduce the search space from 3-D to 2-D (Loidl and
Langer, 1993
; Dorninger et al., 1995
). If such a mechanism
were operating, we would expect that sites closer to the
nuclear envelope should pair more frequently than sites
that are far from the nuclear periphery. Therefore, measurements were made to compare a site's distance from
the nuclear envelope as well as evaluating its radial and
vertical (Rabl) locations in order to look for potential differences between paired and unpaired loci (Table II). Table II shows the average radial and vertical positions of
sites measured from cycle 14 embryos together with the
average distance from the nuclear envelope, calculated separately for paired and unpaired sites. Using Welch's t
test (Zar, 1984
; P 131), the difference between the proximity of a locus to the nuclear envelope for paired and unpaired states was determined to be not significant, even at
the 0.05 significance level. We then tested whether pairing
is restricted to particular domains or territories within the
nucleus. To explore this question, we used cycle 14 nuclei
that are arranged in a monolayer on the surface of the embryo thus fixing the orientation of the nuclei so that radial
and vertical distributions of a site can be measured. Based
on the data from Table II, no discernible difference in spatial localization for the paired and unpaired sites for either radial or vertical positioning were found at the 0.05 significance level, using the same statistical test to compare distance from the nuclear envelope. The results did show that
most sites, paired or unpaired, were contained in a confined spatial distribution imposed by the Rabl orientation
as had been previously reported (Marshall et al., 1996
).
For each individual site, a radial confinement was also
seen, but varied in extent between the different sites. Therefore, we conclude that although sites are spatially
confined to a specified volume or domain in the nucleus,
sites are not specially targeted to a particular nuclear territory in order to be paired.
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Progression in Cycle 14 Interphase Determined by Changes in Nuclear Length
To analytically test models of pairing, quantitative measures of the pairing rate must be determined. However, because FISH must be carried out on fixed organisms, it is usually considered difficult to measure rates using FISH to monitor the homologous sites. Although overall developmental time courses can be determined and are very useful to study trends in pairing over large chromosomal regions, this approach does not provide a quantitative measure of the rate of pairing within a given stage. To circumvent the usual limitations preventing measurement of rates using FISH, we have developed a strategy to accurately gauge elapsed time in cycle 14 interphase by measuring changes in nuclear morphology.
The first step required exploring whether such a functional relationship actually existed for an easily and accurately measurable feature of nuclear morphology such as
nuclear length. It had been previously shown by DIC
microscopy that nuclear volume and diameter increase
monotonically as cycle 14 interphase progresses (Foe and
Alberts, 1985). In our case, changes in nuclear dimensions were tracked by injecting fluorescent dextrans into living
embryos (Kalpin et al., 1994
). and taking 3-D data sets of
the nuclei as they progressed through the cell cycle, starting from early cycle 13 through 60 min of cycle 14 interphase (Fig. 4 A). During interphase, the high molecular
weight (40,000 D) dextrans are excluded by the nuclear
membrane so that nuclei image as dark holes surrounded
by bright fluorescent background (Fig. 4, B and C). However, when the nuclei enter mitosis, the nuclear envelope breaks down allowing the dextran to enter where it had
been previously excluded, so only an even background of
fluorescence is seen (see Fig. 4 B, cyc13 t = 17.5 min). The
start of a cycle is marked by the reappearance of the nuclei
as dark holes (Fig. 4 B, cyc14 t = 0.0 min). When nuclear
length was measured for each timepoint from the volume
of each nucleus (Fig. 4 C), it was found that nuclear length
increases monotonically with time in interphase of cycle 14 (Fig. 4 D). By using a least squares fit to the plotted data, a
quadratic equation was found relating nuclear elongation to elapsed time in cycle 14 interphase (Fig. 4 D). This
equation allows the conversion of nuclear height, which is
readily measured from lamin-stained, in situ hybridized
embryos into a measure of time in cycle 14 interphase providing a means by which to obtain the kinetics of pairing at
that stage. Importantly, previous work using fluorescent
dextrans in the live analysis of nuclear envelope breakdown and reformation in Drosophila embryos has shown
that the dextrans do not disrupt the timing of the nuclear
divisions (Kalpin et al., 1994
).
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Pairing of Histone Loci Occurs Early in Cycle 14
The histone locus seemed the best candidate to focus our analysis of a pairing mechanism. Besides having significantly greater levels of pairing than other loci at cycle 14, the histone locus pairs early (Fig. 3), lessening the probability that the pairing of neighboring sites would complicate the analysis through a tethering effect. From the relationship determined in Fig. 4 D and the FISH data, time profiles for the frequency of pairing as well as for temporal changes in distances between unpaired loci (inter-homologue distances) were generated to characterize pairing of the histone locus (Fig. 5). Interestingly, we found that the pairing of histone locus was relatively rapid with the majority of the pairing (80%) completed in the first 20 min of cycle 14 interphase (total duration ranges from 70-170 min, depending on the domain; Fig. 5, top). At the same time, examination of the time profile of average inter-homologue distances (Fig. 5, bottom) showed that as time increased, the average distance between unpaired loci also increased.
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Distinguishing between Constrained Random Walk and Directed Models for Pairing
Having demonstrated two characteristics of how pairing
developed for the histone locus in cycle 14, we next
wanted to test if the observed behavior of the histone locus conforms to any of the proposed mechanisms for pairing. Two models that might account for how homologous
sites become paired are either a directed motion model or
random walk model for pairing (Fig. 6 A). In a simple directed motion model, homologous sites would be pulled together at some constant velocity. This type of motion
could arise if inter-homologue connections were already in
place to drive homologues closer together by some type of
a contractile force (Holliday, 1968; Maguire, 1983a
; Smithies and Powers, 1986
). Alternatively, if the homologues
were already tethered together at some point, chromosome condensation could potentially bring homologous
sites together (Kleckner et al., 1991
). In contrast, for motion to arise from a random walk, each step taken must be independent from the previous step and random in direction (Crank, 1956
). This results in the relation that the
mean squared displacement in 3-D be given by the equation < r2 > = 6Dt (Berg, 1983
), where t is time and D is
the diffusion coefficient that reflects how fast the random
walk is occurring. Inside a nucleus, equations describing
random walk motion become more complex since the confines of the nuclear volume and nonrandom distributions
of the sites in the nucleus must be taken into account. For
these more complicated situations, simple computer simulations can be used for describing and analyzing such motions.
|
|
To interpret the profiles of histone pairing, we used a
computer simulation based on a standard lattice diffusion
model (Kao and Verkman, 1994; Marshall et al., 1997
) in
order to predict the expected pairing rate for the diffusive
motion. A second simulation was used to predict the outcome of a constant velocity directed motion model. In
both simulations, the basic motion model whether directed
or random walk, was supplemented to take into account both initial position and spatial confinement of the chromatin within the nucleus. From an earlier study (Marshall
et al., 1996
), we know that histone sites are not distributed
randomly throughout the nucleus. To incorporate this information into the algorithm, the initial distribution of histone loci was specified by the average radial (ro) and vertical positions (zo) and their respective standard deviations
(
ro and
zo) measured from nuclei representing the earliest time point in interphase (Fig. 7). Spatial confinement was modeled by limiting motion within a cylindrical volume as given by the radial boundary and vertical boundary. These values are obtained by measuring, respectively,
the average standard deviations,
r and
z, for the radial
and vertical positions of the loci for the duration of the
pairing and setting the boundaries at 1.5 times
. (Fig. 7,
Table II), which in turn is a measure of the potential range
of radial and vertical position (see Materials and Methods).
Implicit in the simulations is the assumption that there is a
100% pairing probability once homologous loci come within
a distance, d, which is the diameter of the signal.
The result of using such simulations to characterize the behavior of the pairing of the histone loci is given in Fig. 6 for changes in pairing frequency and inter-homologue distances, both for the case of diffusional motion and directed motion at constant velocity. Profiles for both the frequency of pairing and the inter-homologue distance as a function of time have been plotted for several values of the diffusion coefficient and velocity (Fig. 6, B and C). As might be expected, the time profiles for the frequency of pairing show a more gradual approach towards the completion of pairing in the random walk model (Fig. 6 B, top) as compared with the faster approach predicted by the model using directed motion (Fig. 6 C, top). Similarly, for time profiles expressing the changes in inter-homologue distance, we also see qualitatively distinct behavior for the different models. In the case of random walk, as sites that are near each other pair and are no longer included in the calculation of average distance between unpaired homologous sites, we intuitively expect that the average inter- homologue distance should shift to greater distances with time, while also showing the distances leveling off after longer time periods as a result of the imposed spatial confinement. The bottom panel of Fig. 6 B clearly demonstrates that this, indeed, is the case for this simulation. In contrast, we would expect an entirely different behavior for the inter-homologue distances based on a directed motion model. Here, as shown in the bottom panel of Fig. 6 C, the average distance between homologous sites should monotonically decrease, since by this model, sites are being pulled together at a constant velocity.
We then compared the actual measured profiles of histone pairing with those generated by the simulations. We
only found good correlation in the pairing frequency plot
between the experimental data and the simulations when
motion is predicted to occur by a constrained random walk
with a diffusion coefficient of D = 1.0 × 1011 cm2/s (Fig.
6 B, top). In contrast, the shape of the pairing frequency plots for the directed motion model did not fit the experimental data for any value of velocity (Fig. 6 C, top). When
comparing actual and simulated inter-homologue distances (Fig. 6 B, bottom), the experimentally derived values again agreed only in the case when motion is modeled
as a random walk where both the simulation and actual
data show an increasing distance between unpaired loci with elapsed time. In contrast, when the measured profiles
of histone pairing were compared with those obtained
from the simulations based on the directed motion model
(Fig. 6 C), little correspondence could be detected. This is
particularly evident in the plots of inter-homologue distance (Fig. 6 C, bottom) where the simulations predict a
decrease in the distance whereas the actual data shows a
distinct increase. From these comparisons, we thus conclude that the pairing behavior of the histone locus is consistent with a random walk model for chromatin motion.
Perturbation of Pairing as a Consequence of Chromosome Rearrangement
The lt×13 strain (Wakimoto and Hearn, 1990) contains a
reciprocal translocation between the centromeric heterochromatin on chromosome arm 2L and a subtelomeric site
on arm 3R that moves the entire histone locus near the
end of 3R (Fig. 8 A). Surprisingly, in strains homozygous
for the lt×13 chromosome translocation, pairing levels for
the histone locus during cycle 14 was found to be ~30%
on average compared with ~70% for wild type (Hiraoka
et al., 1993
). In this strain, the average vertical position of
the histone locus measured at the beginning of cycle 14 is
shifted from the center of the nucleus (as seen in wild-type
strains) to a position ~1.5 µm lower. Why this positional
change would result in much lower levels of histone pairing was never clear given that both loci are shifted equally in this homozygous translocation. Could it be that the intrinsic pairing ability of the histone locus is somehow affected by this translocation? One possibility would be that
histone pairing is aided by other pairing sites and that the
translocation removes it from these sites. This seems unlikely given the independence of the histone pairing from
neighboring sites as shown earlier in this paper and the
fact that high levels of pairing (83%) are again seen at the
13 h AED timepoint. Another possibility is that the translocation alters the chromosome context of the histone locus, for example, by separating it from regulatory domains
linked in cis. Although this is a formal possibility, we note
that the breakpoint in this translocation is not in, or even
near, the histone locus, and so the flanking chromatin
around the histone locus is likely to be the same in the
translocated histone locus. An alternate explanation is
that the large-scale nuclear positioning of the histone locus
may be different in the translocation. In the Hiraoka study
(Hiraoka et al. 1993
), a plot of the distribution of histone
loci for the wild-type and homozygous lt×13 strain revealed
a slightly wider range in the distribution for the lt×13 strain.
Given that histone pairing occurs by diffusion, the fact that
histone loci now start farther apart on average may explain why, granted the same amount of time, pairing levels
for the lt×13 strain are lower. To test this possibility, we
measured the initial variances in the radial and vertical positions for the lt×13 (
ro = 1.1 and
zo = 1.7; compare with
wild type,
ro = 0.4 and
zo = 0.4) and used simulations to
predict the pairing behavior. The resulting profile (Fig. 8 B)
shows that given this initial distribution of histone loci, a
lowered pairing frequency is indeed expected. Moreover,
similar levels of pairing were observed here (for t = 15 min, pairing level = 40% for lt×13; compare this to 70% for
wild type as were seen in the Hiraoka study (Hiraoka et al.
1993
; ~30% for lt×13 and ~70% for wild type). The slight
discrepancy between the pairing levels for lt×13 from the
different studies, 40 vs 30%, is most likely attributed to the
fact that, in the Hiraoka study, no attempts were made to
distinguish between embryos at different elapsed times in
cycle 14. From these results, we conclude that the inherent
pairing ability of the histone locus is not affected by the
translocation, but rather, the wider distribution (i.e., larger
variance) imposed by histone's new location is responsible
for the lower frequency of pairing seen in these strains.
This result, moreover, dramatically confirms the predictive power of the constrained random walk model, further
increasing our confidence in its validity.
|
Disruption of Pairing By Mitosis
To determine whether the pairing interactions are maintained throughout the cell cycle, we examined the level of
histone pairing at different mitotic stages. During mitosis,
several forces act upon chromosomes eventually resulting
in chromosome separation to opposite poles (reviewed in
Gorbsky, 1992). These forces include chromosome condensation, forces involved in metaphase congression and
forces contributing to anaphase separation, all of which
could potentially disrupt any homologous pairing associations formed in the preceding interphase. Evidence that
pairing is indeed disrupted during mitosis is indicated here
by the observation of a decrease in pairing levels for the
histone locus in the transition between cycle 13 and cycle
14 interphase. At cycle 13 interphase, the average pairing
frequency for this locus is 62% (Fig. 3) but at the beginning of cycle 14 interphase, the pairing level is down to
22% (Fig. 5 A). The reduction of the pairing level to 22%
suggests that homologous pairing is completely dissociated
during passage through mitosis. To further narrow down
the timing of this disruption, we examined the pairing levels for the histone locus at selected stages of cycle 13 mitosis. During metaphase of cycle 13, when the chromosomes
are maximally condensed, the association level for the histone locus is 63% (Fig. 9 A). Since these values are equivalent to what is found during cycle 13 interphase, disruption of the pairing association has not occurred up to this point. Note that no gain in the pairing levels is seen either, indicating that no significant pairing is occurring during passage through the prophase (50%) and metaphase stages.
Next, we examined nuclei undergoing anaphase and here a
dramatic disruption in the pairing was observed (Fig. 9 B).
Anaphase figures were found with 4 (72%), 3 (18%), or 2 (10%) FISH signals for the histone locus. Up to four signals are seen in anaphase due to sister chromatid separation unlike the one or two signals found during metaphase
when sister chromatids are still associated. Because each
anaphase figure eventually results in two telophase nuclei,
we counted each set of sister chromosomes as a separate
nucleus in our calculation of pairing frequency in order to
take into account any anaphase figures with three FISH
signals (one paired, one unpaired). This results in a pairing
frequency of 19% for the histone locus at anaphase. We
conclude that it is during anaphase that pairing interactions are dissociated thus explaining the low levels of pairing frequency found at the beginning of cycle 14 interphase.
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Discussion |
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Mechanism For Homologue Pairing
Greatly differing views exist for the mechanism whereby
chromosomes find their homologous partners. On one
hand, there are several models that propose active movements on the part of chromosomes to bring homologous
sites together. Holliday (1968) postulated early on that
one way for homologues to be drawn together is through the contraction of fibrillar connectors extending between
specific DNA sequences on homologous chromosomes. A
similar proposal was offered by Maguire (1983a)
based
on observations of homologous alignment at a distance
(Maguire 1983b
) and on reports of the existence of premeiotic and early meiotic intranuclear bundles of microfilaments in microsporocytes (Bennett et al., 1979
). More recently, Kleckner et al. (1991)
, modifying a proposal by
Smithies and Powers (1986)
, alternatively favored the view
that after the initial formation of unstable DNA-DNA interactions through chance encounters, chromosome condensation may further drive homologues closer together.
A common feature in all of the aforementioned models is
that at some point homologous regions are directed towards each other. This is in contrast to the opposing view
that random contacts of homologous sequences, brought
about by diffusion of chromatin, is the primary mode in establishing homologous pairing (e.g., Brown and Stack,
1968
).
In this study, we provide the first demonstration of the means by which pairing takes place. By measuring the actual kinetics of pairing and using simulations based on directed and random walk models, we show that pairing of the histone locus during Drosophila embryonic development is consistent with a mechanism that relies on finding a homologous locus through diffusive motion of the chromatin.
The occurrence of random walk motion of chromatin
during interphase has been confirmed in several organisms. Recently, Marshall et al. (1997) directly measured
chromatin motion in live interphase nuclei in Drosophila
and budding yeast and found in all cases that the observed
loci moved by random walk motion. The diffusion coefficient, D = 1.0 × 10
11 cm2/s that we obtained from our
pairing analysis is in excellent agreement with D = 1.25 × 10
11 cm2/s obtained in the Marshall et al. (1997)
study
directly measuring chromatin motion in living Drosophila
embryonic nuclei. Although the 359-bp satellite repeat on
chromosome X and not the histone locus was analyzed in
the case of Drosophila, the diffusion coefficient obtained
for this locus corresponded well with the value acquired by our analysis of the histone pairing profile. Even apart
from simulations, it can be seen that the magnitude of the
diffusion constant reported by Marshall et al. (1997)
is
roughly consistent with the spatial and temporal scale of
the homologue pairing problem. As a crude calculation,
we recognize that the mean squared change in the mutual
distance r between two diffusing loci is given by the equation < r2 > = 4Dt (von Smoluchowski, 1917
). Thus in 10 min, given a diffusion constant on the order of 10
11 cm2/s
(Marshall et al., 1997
), the two spots would move towards
or away from each other by an average distance of ~1.5
µm. Thus the micron-scale movements required for homologue pairing are predicted to take place on roughly the
10-min time scale, consistent with the duration of interphase. The fact that the diffusion coefficient obtained
from the histone pairing profile agrees with the value obtained in the independent study of chromatin motion in
Drosophila gives further support that pairing of the histone locus does indeed occur via random walk motion of
chromatin.
Although this study strongly suggests a diffusion-driven
random walk mechanism for homologue pairing, there may
be other mechanisms that pair other sites. There still could
be a combination of mechanisms including condensation
and/or active processes that also play important roles in
achieving full homologous association. Active movement of
telomere-led chromosome motions that occur preceding meiosis in fission yeast (Chikashige et al., 1994) may be one example of how active processes may be used to create conditions that promote the homology search.
Is Pairing Permanent or Transient?
Our model for attainment of pairing by a random walk
search makes the assumption that once two homologous
loci encounter each other and pair, that they subsequently
remain paired and do not dissociate. In this model, differences in pairing levels between different loci reflect differences in the rates at which pairing is first attained. However, an alternate possibility to this kinetic model would
be transient pairing followed by dissociation, with the observed pairing levels reflecting the equilibrium balance between association and dissociation. Indeed, it has been
pointed out by Kleckner and Weiner (1993) that such a
transient pairing could be advantageous in resolving interlocks during meiotic homologue pairing.
Clearly, because pairing levels of the histone locus increase continuously during the first 20 min of cycle 14 interphase, any equilibrium that is attained must take at least 20 min. Indeed, it must take even longer since attainment of maximum pairing levels takes even more time for other loci. Thus, during this time frame it cannot be the case that differences in pairing levels simply reflect equilibrium balance of association and dissociation, as a steady state has not yet been reached. Nevertheless, although we can thus conclude that differences in pairing are the result of kinetic, rather than equilibrium differences, it is still a formal possibility that some of the paired loci can dissociate, even though they must do so much less frequently than they associate (otherwise pairing levels would not increase). To test this idea we consider the predicted consequences of the transient pairing model on the behavior of the average distance between unpaired loci versus time. Transient pairing predicts that there are two types of unpaired sites: sites that have never paired, and sites that have paired but dissociated. Sites that have never paired will be distributed the same way as all the sites were at the beginning of interphase, i.e., randomly. But unpaired sites generated by dissociation of paired sites will not be randomly distributed but will on the contrary be much closer together, since they had recently been overlapping and only a limited time has passed during which they can diffuse apart. Assuming that the dissociation, like standard macromolecular dissociations, is a first order process with respect to the number of paired loci, then the number of unpaired loci resulting from dissociation will be directly proportional to the number of paired loci at any given time. This would predict then that as the frequency of paired sites increases over time, that the fraction of unpaired sites generated by dissociation would similarly increase, and because such pairs of sites are nonrandomly close together, therefore the average distance between unpaired loci is predicted to decrease. But in fact our data indicates that the distance between unpaired loci actually increases over time. Therefore, we conclude that dissociation of paired loci, if it happens at all, must be a rather low probability event and therefore the pairing we observe is not an equilibrium association/dissociation process, but rather an irreversible adsorption process, with paired loci remaining paired more or less permanently. Whether or not this will also be true of meiotic homologue pairing remains to be determined.
Disruption of Pairing Interactions by Mitosis
Our histone results indicate that pairing interactions begin
to form at the start of interphase. During interphase when
pairing is in progress, chromosomes are at their most decondensed state, in agreement with previous suggestions
that pairing occurs when chromatin is not greatly compacted (Kleckner et al., 1991; Dawe et al., 1994
). During
this time, S phase, DNA replication, and histone gene
transcription also occur concomitantly (Edgar and Schubiger, 1986
; Edgar and O'Farrell, 1990
) with no obvious
interference to the pairing interactions. Nor is there any
disruption due to forces involved in chromosome condensation or metaphase congression as seen by the maintenance in pairing levels up to the metaphase stage. Consequently, we believe that relatively strong interactions are
created between the two homologous regions when they
contact, which in mitosis, are only disrupted during
anaphase. A possible explanation for this disruption is that
spindle forces acting to segregate the sister chromatids to
opposite poles somehow exert enough force or create
enough agitation to cause dissociation of homologous
pairing. For example suppose that each chromatid of one
homologue interacts with just one chromatid of the other homologue. To maintain pairing, the kinetochores on
these two homologous chromatids must segregate to the
same pole, and if, due to random segregation of sister kinetochores, they segregate to opposite poles, clearly homologous pairing will be disrupted. We consider this to be
a very likely possibility. However, it is also possible that
the same factors regulating the end of sister chromatid cohesion may also release homologous associations.
The fact that anaphase almost completely disrupts the
pairing formed during the previous interphase has bearing
on the proposed concept of graduality in the pairing
process. It has been suggested that meiotic pairing results
from gradually increasing the number of loci that are
paired over the course of several cell cycles preceding meiosis (Brown and Stack, 1968). However, if it is true that
complete disruption of pairing interactions occurs at every mitosis, no significant accumulation of pairing should be
obtained from successive cell cycles. Rather, in order for
pairing to be established over long stretches of chromatin,
it seems that a long interphase or an uninterrupted period
during which chromosomes are still decondensed is required, particularly if part or all of the pairing is to occur
by random walk motion. The importance of the length of
the cell cycle has been previously stressed by Golic and
Golic (1996)
. In their study, they found that minute mutations that significantly slow the rate of cell division in imaginal discs could suppress the effects of rearrangements on transvection. A longer period where chromosomes are still decondensed also coincides nicely with observations in several organisms that the duration of
premeiotic interphase (Bennett et al., 1973
; Williamson et al.,
1983
) and prophase I (reviewed in Bennett, 1977
) are
quite lengthy in comparison to their mitotic counterparts.
We must point out that although we observe homologues
to dissociate during anaphase, it remains a formal possibility that some invisible connection remains between them
that allows them to reestablish pairing more efficiently in
the next interphase. Such a persistent linkage would allow
for gradual attainment of pairing over multiple cell cycles.
However, since there is at present no evidence whatsoever for such a linkage, we consider this possibility to be remote.
Reevaluation of the Onset of Pairing for the Histone Locus
The requirement for a sufficiently long interphase period
may also explain why in early nuclear divisions of Drosophila embryogenesis the level of pairing of the histone
locus on average is much lower than the level seen at cycle
14 (Hiraoka et al., 1993). The dramatic change in the level
of histone pairing at cycle 14 was used to propose that the
histone locus had the capability to pair only after the transition to cycle 14. We now believe that it is timing and not
competence for pairing that explains the change in pairing levels. We propose that the pairing capability for the histone locus exists for all cell cycles, but that the shorter cell
cycle times for early divisions (e.g., cycle 12, 13 min; cycle
13, 17 min, times include mitosis (Foe and Alberts, 1983
),
do not allow sufficient time to achieve high levels of pairing. Corroborating evidence is that the cycle 13 pairing frequency of 61% measured in this study (Fig. 3) shows that
the histone locus, indeed, becomes paired before the transition to cycle 14. One possibility why only a 32% pairing
frequency for cycle 13 was seen in the previous work may
be that only earlier cycle 13 embryos were examined due to differences in the collection temperature, leading to the
impression of a very sharp change in the pairing frequency
at the transition between cycle 13 and 14.
What Governs the Ability of Homologues to Pair?
The variation in the temporal pattern of the attainment of
pairing seen during Drosophila development in this study
raises the question why certain sites attain high levels of
pairing very early in development whereas other sites take
much longer. This question can be said to relate to the
more general issue of what might govern the ability for homologous sites to pair. An answer to this question will not
only help us understand how pairing develops to the point
that a whole chromosome is completely aligned but will
also help us comprehend observations that in most somatic tissues, except in the case of Dipterans, homologous
pairing specifically occurs for some loci but not for others.
For a long time, conflicting evidence existed whether somatic pairing, outside what was seen for Dipteran insects,
occurred at all (Haaf and Schmid, 1991). However, recent
evidence now indicates that somatic pairing does occur in
a site-specific manner and that the contradictory results obtained previously arose from the fact that such pairing is
highly dependent on the particular tissue being examined
and the time frame being studied. For example, using 3-D
FISH techniques combined with fluorescence-activated
cell sorting, LaSalle and Lalande (1996)
found in human
lymphocytes that homologous association occurred specifically at the imprinted 15q11-q13 regions only during late
S phase of the cell cycle. A related observation was made
for the existence of a tissue dependence for somatic pairing in earlier work by Arnoldus et al. (1989)
showing that
homologous association is detected for human chromosome 1 from nuclei taken from cerebellar tissue but not in
nuclei from cerebral tissue. Even in Drosophila, where somatic homologue pairing is complete in many cases, there
is also evidence suggesting inherent differences in pairing
ability of different loci in meiosis (McKee et al., 1993
). For
example, McKee et al. (1993)
examining the distribution of autosomal pairing ability in Drosophila males during
meiosis by characterizing the pairing and segregation patterns of males carrying various transpositions of regions
derived from chromosome 2 into Y, identified a strong
pairing site found to contain the histone locus. Other studies focusing instead on the sex chromosomes show that the
rDNA locus is a strong pairing site as well (reviewed in
McKee, 1996
). Thus in many organisms, it appears that
different sites have different inherent tendencies to homologously pair, but the basis for these differences is currently unknown.
In this paper, we have examined and eliminated several possibilities as reasons why certain sites may demonstrate preferential pairing abilities over others. In the two loci that paired the earliest, histone and Rsp, a common feature in both is that each locus consists of several repetitions of their respective sequence. However, examination of other loci with repeated sequences (e.g., AACAC) show quite clearly that repetition alone is not sufficient to confer early participation in the pairing process. Although it was possible that there could be fundamental differences in pairing at euchromatic and heterochromatic loci, the careful, systematic comparison performed here shows no consistent differences.
There remain several possible explanations for differences in pairing ability. One suggestion is that transcriptional activity may also correlate with pairing ability (McKee, 1996) since both the histone and rDNA loci, found to
be strong pairing sites during male meiosis are also known
to be highly transcribed. However, it is unclear whether
the heterochromatic Rsp locus, one of the earliest pairing
sites in the embryo, is even transcribed. The correlation
between transcription and pairing is thus far from compelling. Another possibility is that differences in pairing could
arise from differences in protein-binding sites at different loci. If homologue pairing is mediated by chromatin-associated proteins, then differences in the affinity of these
proteins for certain regions will be reflected in differences
in the propensity for those regions to pair. Thus, the explanation for differences in pairing ability remains an open
question requiring further investigation.
The Role of Nuclear Organization in Homologue Pairing
From our profile of the pairing frequency for the histone
locus, we found experimentally that pairing can occur at a
significant rate, such that, by the first 20 min of cycle 14 interphase, 80% of the nuclei contain paired histone loci. It
was also especially evident from monitoring histone pairing in the lt×13 strain, that the observed pairing frequencies
strongly depend on the spatial probability distribution of
each of the sites in the unpaired state. Thus, we would like
to speculate that a key determinant of homologous pairing
is the 3-D architecture of the nucleus. As discussed earlier,
it has been shown that in the Drosophila early embryo a
given locus occupies a discrete subregion within the nucleus (Marshall et al., 1996). This organization stems from a combination of an overall centromere-telomere spatial
organization (the classical "Rabl" configuration), as well
as more specific patterning. As a result, a given locus is
found to occupy a disk- or annulus-shaped volume within
the nucleus, whose vertical position depends on the distance from the centromere and whose radial extent is
based on a consistent distance from the nuclear envelope
(NE). In particular, a set of ~10-15 sites per chromosome
arm have been identified in the Drosophila embryo that
are closely associated with the NE, whereas another set of
sites have been identified that are nonrandomly localized
to the interior of the nucleus. Homology search by any
given locus will thus be confined to the small subregion in
which it is localized. We propose that because both homologous copies of such a locus will, in general, occupy the
same subregion, the homology search will be greatly facilitated. Moreover, time spent exploring nonhomologous
loci will be greatly reduced, since most nonhomologous
loci will be restricted to separate regions of the nucleus
and will never come into contact during the pairing process. Thus, a highly defined nuclear architecture, such as is
clearly seen in the Drosophila embryo, can dramatically enhance the rate of homology searching. We can carry this
hypothesis one step further: computer simulations in this
study indicate that the rate of homology searching depends critically on both the initial distance between the
loci and the size of the region in which the search takes
place. Loci with more peripheral localizations will be
found within a significantly larger annular region than loci
positioned more internally, and thus the homology search should take longer. Thus, we predict that the sites that pair first will be those that are most internally localized. Interestingly, both histone and Rsp, the first sites to pair on
chromosome 2, are nonrandomly internal (Marshall et al.,
1996
), indeed they are the only such sites known on chromosome 2. A picture is thus emerging in which position
within the nucleus, as specified via the nuclear architecture, plays a critical role in homologue pairing, and could
in fact explain why some sites pair much earlier than others.
![]() |
Footnotes |
---|
Address correspondence to John W. Sedat, Department of Biochemistry and Biophysics, University of California, San Francisco, San Francisco, CA 94143-0554. Tel.: (415) 476-2489. Fax: (415) 476-1902. E-mail: sedat{at}msg.ucsf.edu
Received for publication 26 August 1997 and in revised form 20 January 1998.
Jennifer C. Fung and Wallace F. Marshall's present address is MCDB Dept., Yale University, New Haven, CT 06520. ![]() |
Abbreviations used in this paper |
---|
3-D, three-dimensional; AED, after egg deposition; FISH, fluorescence in situ hybridization; NE, nuclear envelope; Rsp, responder.
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